Targeted Mutagenesis at Charged Residues in <Emphasis Type="Italic">Bacillus sphaericus</Emphasis> BinA Toxin Affects Mosquito-Larvicidal Activity

The mosquito-larvicidal binary toxin from Bacillus sphaericus is composed of two polypeptides called BinA and BinB with molecular masses of approximately 42 and 51 kDa. Both components are required for full activity, with BinB acting as a specificity determinant and BinA being responsible for toxic action. To investigate the role of the selected charged residues in BinA, four mutants were generated by replacing charged amino acids with alanine (R97A, E98A, R101A, and E114A). All mutant proteins were produced at high levels and formed inclusion bodies similar to that of the wild type. Mosquito-larvicidal assays against Culex quinquefasciatus larvae revealed that the mutant R97A completely lost its activity and mutants E98A, R101A, and E114A showed significantly reduced toxicity. Intrinsic fluorescence spectroscopy analysis indicated that alanine substitutions at these positions did not alter the overall structure of the toxin. Binding of the mutants to BinB was not different from that of the wild type, suggesting that these mutations did not affect BinA-BinB interaction. Results demonstrated that R97, E98, R101, and E114 neither play a direct role in maintenance of BinA structure nor are involved in BinA-BinB interaction. Since these residues are required for full activity, they may play an important role during toxin internalization and/or toxic action of BinA inside the target cells.     

Implications of high-molecular-weight oligomers of the binary toxin from Bacillus sphaericus

The mosquito-larvicidal binary toxin produced by Bacillus sphaericus is composed of BinB and BinA, which have calculated molecular weights of 51.4 and 41.9 kDa, respectively. NaOH extracts of B. sphaericus spores were analyzed using SDS-PAGE. Stained gels showed bands with molecular weights corresponding to those of BinB and BinA as well as two additional bands at 110 and 125 kDa. The matrix-assisted laser desorption/ionization mass spectrum of the purified 110 and 125 kDa bands showed two peaks at 104,160 and 87,358 Da that are assigned to dimers of BinB and BinA, respectively. Mass spectral analysis of trypsin-digested 110 and 125 kDa bands showed peaks at 51,328, 43,523, 43,130, and 40,832 Da that assigned to undigested BinB, two forms of digested BinB and digested BinA, respectively. Dynamic light scattering studies showed a solution of the purified 110 and 125 kDa bands was comprised almost entirely (99.6% of total mass) of a particle with a hydrodynamic radius of 5.6+/-1.2 nm and a calculated molecular weight of 186+/-38 kDa. These data demonstrate that the binary toxin extracted from B. sphaericus spores can exist in solution as an oligomer containing two copies each of BinB and BinA.     

Expression and purification of the active soluble form of Bacillus sphaericus binary toxin for structural analysis

The binary toxin produced from Bacillus sphaericus is highly toxic against larvae of Culex and Anopheles mosquitoes. The two major components of the binary toxin are 42-kDa BinA and 51-kDa BinB, which are produced as crystalline inclusions during sporulation. Currently, there is no detailed knowledge of the molecular mechanism of the binary toxin, mainly due to the lack of structural information. Herein, we describe an expression protocol with modified conditions allowing production of soluble, biologically active BinA and BinB for further structural analysis. The binA and binB genes from B. sphaericus 2297 strain were independently cloned and fused with a polyhistidine tag at their N-termini. Both (His)(6)-tagged BinA and (His)(6)-tagged BinB were expressed as soluble forms at low temperature. Highly pure proteins were obtained after two-step purification by Ni-NTA affinity and size exclusion chromatography. In vitro activation by trypsin digestion generated a resistant fragment, of 40kDa for BinA, and of 45kDa for BinB, and an oligomeric complex of BinA and BinB in solution was observed after proteolytic activation. Their functional and structural properties were confirmed by a biological assay and far-UV circular dichroism, respectively. The mixture of BinA and BinB, either as a protoxin or as a trypsin-activated form, exhibited high mosquito-larvicidal activity against Culex quinquefasciatus larvae with LC(50) of about 10ng/ml, while no toxicity was observed from the single binary toxin component. Results from far-UV circular dichroism of BinA and BinB suggest the presence of mainly β-structure. The expression and purification protocols reported here will be useful for the production of the active and homogeneous binary toxin to allow further detailed structural investigation.     

Functional characterization of truncated fragments of Bacillus sphaericus binary toxin BinB

Bacillus sphaericus produces a mosquitocidal binary toxin composed of two subunits, BinA (42 kDa) and BinB (51 kDa). Both components are required for maximum toxicity against mosquito larvae. BinB has been proposed to provide specificity by binding to the epithelial gut cell membrane, while BinA may be responsible for toxicity. To identify regions in BinB responsible for receptor binding and for interaction to BinA, we used six BinB shorter constructs derived from both the N-terminal and the C-terminal halves of the protein. All constructs expressed as inclusion bodies in Escherichia coli, similarly to the wild-type protein. A marked decrease in larvicidal activity was observed when BinA was used in combination with these BinB constructs, used either individually or in pairs from both N and C-halves of BinB. Nevertheless, immunohistochemistry analyses demonstrate that these constructs are able to bind to the epithelium gut cell membrane, and in vitro protein-protein interaction assays revealed that these constructs can bind to BinA. These results show that fragments corresponding to both halves of BinB are able to bind the receptor and to interact with BinA, but both halves are required by the toxin to exhibit full larvicidal activity.     

Cys31, Cys47, and Cys195 in BinA Are Essential for Toxicity of a Binary Toxin from Bacillus sphaericus

The mosquito larvicidal binary toxin produced by Bacillus sphaericus is composed of 2 proteins called BinA and BinB. While BinB acts as specificity determinant, BinA is expected to bind to BinB, translocates into cytosol, and exerts its activity via an unknown mechanism. To study the role of cysteine in BinA, 3 cysteine residues were substituted by alanine and serine. Substitution at Cys195 significantly reduced the toxin activity, whereas substitution at Cys31 and Cys47 abolished its toxicity. Intrinsic fluorescent analysis suggested that all mutant proteins should have similar tertiary structure to that of the wild type. Analysis of the mutant protein on sodium dodecyl sulfate–polyacrylamide gel electrophoresis with and without a reducing agent indicated that all 3 cysteine residues were not involved in disulfide bond formation within the BinA molecule. This is the first report to demonstrate that cysteine residues at 3 positions in BinA are required for full toxicity of the binary toxin. They may play a critical role during oligomerization or interaction between BinA and BinB to form the active complex.     

Permeabilization of Model Lipid Membranes by Bacillus sphaericus Mosquitocidal Binary Toxin and its Individual Components

The high larvicidal effect of Bacillus sphaericus (Bs), a mosquito control agent, originates from the presence of a binary toxin (Bs Bin) composed of two proteins (BinA and BinB) that work together to lyse gut cells of susceptible larvae. We demonstrate for the first time that the binary toxin and its individual components permeabilize receptor-free large unilamellar phospholipid vesicles (LUVs) and planar lipid bilayers (PLBs) by a mechanism of pore formation. Calcein-release experiments showed that LUV permeabilization was optimally achieved at alkaline pH and in the presence of acidic lipids. BinA was more efficient than BinB, BinB facilitated the BinA effect, and their stoichiometric mixture was more effective than the full Bin toxin. In PLBs, BinA formed voltage-dependent channels of ≈100–200 pS with long open times and a high open probability. Larger channels (≥400 pS) were also observed. BinB, which inserted less easily, formed smaller channels (≤100 pS) with shorter mean open times. Channels observed after sequential addition of the two components, or formed by their 1:1 mixture (w/w), displayed BinA-like activity. Bs Bin toxin was less efficient at forming channels than the BinA/BinB mixture, with channels displaying the BinA channel behavior. Our data support the concept of BinA being principally responsible for pore formation in lipid membranes with BinB, the binding component of the toxin, playing a role in promoting channel activity. Received: 29 March 2001/Revised: 20 July 2001     

Crystal structure of BinB: A receptor binding component of the binary toxin from Lysinibacillus sphaericus

The binary toxin (Bin), produced by Lysinibacillus sphaericus, is composed of BinA (42 kDa) and BinB (51 kDa) proteins, which are both required for full toxicity against Culex and Anopheles mosquito larvae. Specificity of Bin toxin is determined by the binding of BinB component to a receptor present on the midgut epithelial membranes, while BinA is proposed to be a toxic component. Here, we determined the first crystal structure of the active form of BinB at a resolution of 1.75 Å. BinB possesses two distinct structural domains in its N‐ and C‐termini. The globular N‐terminal domain has a β‐trefoil scaffold which is a highly conserved architecture of some sugar binding proteins or lectins, suggesting a role of this domain in receptor‐binding. The BinB β‐rich C‐terminal domain shares similar three‐dimensional folding with aerolysin type β‐pore forming toxins, despite a low sequence identity. The BinB structure, therefore, is a new member of the aerolysin‐like toxin family, with probably similarities in the cytolytic mechanism that takes place via pore formation. Proteins 2014; 82:2703–2712. © 2014 Wiley Periodicals, Inc.     

Interaction between mosquito-larvicidal Lysinibacillus sphaericus binary toxin components: Analysis of complex formation

The two components (BinA and BinB) of Lysinibacillus sphaericus binary toxin together are highly toxic to Culex and Anopheles mosquito larvae, and have been employed world-wide to control mosquito borne diseases. Upon binding to the membrane receptor an oligomeric form (BinA2.BinB2) of the binary toxin is expected to play role in pore formation. It is not clear if these two proteins interact in solution as well, in the absence of receptor. The interactions between active forms of BinA and BinB polypeptides were probed in solution using size-exclusion chromatography, pull-down assay, surface plasmon resonance, circular dichroism, and by chemically crosslinking BinA and BinB components. We demonstrate that the two proteins interact weakly with first association and dissociation rate constants of 4.5 × 10³ M^?1 s^?1 and 0.8 s^?1, resulting in conformational change, most likely, in toxic BinA protein that could kinetically favor membrane translocation of the active oligomer. The weak interactions between the two toxin components could be stabilized by glutaraldehyde crosslinking. The cross-linked complex, interestingly, showed maximal Culex larvicidal activity (LC₅₀ value of 1.59 ng mL^?1) reported so far for combination of BinA/BinB components, and thus is an attractive option for development of new bio-pesticides for control of mosquito borne vector diseases.     

Efficient Expression of the Mosquito Larvicidal Binary Toxin Gene from <Emphasis Type="Italic">Bacillus sphaericus</Emphasis> in <Emphasis Type="Italic">Escherichia coli</Emphasis>

The binary toxin gene encoding BinA (42 kDa) and BinB (51 kDa) from Bacillus sphaericus strain 2297 was cloned and expressed in E. coli. Low expression level was found when both proteins were expressed from a single operon. High expression was observed when the gene encoding an individual protein was placed downstream of the T7 promoter. The expression level of BinB was not different when expressed alone (non-fusion) or as a fusion form with T7 peptide (T7-BinB). Both forms of BinB were equally stable. Unlike BinB, the non-fusion form of BinA was less stable than T7-BinA. The mosquito larvicidal test showed that BinA or BinB alone was not toxic to mosquito larvae, but high toxicity was found when both BinA and BinB were applied. The results suggest that a short peptide of T7 linked to the N-terminus of either BinA or BinB does not affect their toxicity, but may make the toxin, especially BinA, more stable.     

Purification and characterization of mosquitocidal Bacillus sphaericus BinA protein

Certain strains of Bacillus sphaericus produce a highly toxic mosquito-larvicidal binary toxin during sporulation. The binary toxin is composed of toxic BinA (41.9 kDa) and receptor binding BinB (51.4 kDa) polypeptides and is active against vectors of filariasis, encephalitis and malaria. The toxin has been tested with limited use for the control of vector mosquitoes for more than two decades. The binA gene from a local ISPC-8 strain of B. sphaericus that is highly toxic to Culex and Anopheles mosquito species was cloned into pET16b and expressed in Escherichia coli. The purified BinA protein differs by one amino acid (R197 M) from BinA of the highest toxicity strains 1593/2362/C3-41. Majority of the expressed protein was observed in inclusion bodies. BinA inclusions alone from E. coli did not show toxic activity, like reported previously. However, the active form of BinA could be purified to homogeneity from the soluble fraction of E. coli cell lysate, grown at reduced temperature after isopropyl β-d-thiogalactopyranoside induction. The purified BinA protein with and without poly-histidine tag showed LC₅₀ dose of 82.3 and 66.9 ng ml⁻¹, respectively, at 48 h against Culex quinquefasciatus larvae. The secondary structure of BinA is expected to be mainly β strands as estimated using far-UV circular dichroism. The estimates matched well with the secondary structure predictions using amino acid sequence. This is the first report of large-scale purification and accurate toxicity estimation of soluble B. sphaericus BinA. This can help in design and synthesis of improved bacterial insecticide.     

Structurally conserved aromaticity of Tyr249 and Phe264 in helix 7 is important for toxicity of the Bacillus thuringiensis Cry4Ba toxin

Functional elements of the conserved helix 7 in the poreforming domain of the Bacillus thuringiensis Cry delta- endotoxins have not yet been clearly identified. Here, we initially performed alanine substitutions of four highly conserved aromatic residues, Trp(243), Phe(246), Tyr(249) and Phe(264), in helix 7 of the Cry4Ba mosquito-larvicidal protein. All mutant toxins were overexpressed in Escherichia coli as 130-kDa protoxins at levels comparable to the wild-type. Bioassays against Stegomyia aegypti mosquito larvae revealed that only W243A, Y249A or F264A mutant toxins displayed a dramatic decrease in toxicity. Further mutagenic analysis showed that replacements with an aromatic residue particularly at Tyr(249) and Phe(264) still retained the high-level toxin activity. In addition, a nearly complete loss in larvicidal activity was found for Y249L/F264L or F264A/ Y249A double mutants, confirming the involvement in toxicity of both aromatic residues which face towards the same direction. Furthermore, the Y249L/F264L mutant was found to be structurally stable upon toxin solubilisation and trypsin digestion, albeit a small change in the circular dichroism spectrum. Altogether, the present study provides for the first time an insight into the highly conserved aromaticity of Tyr(249) and Phe(264) within helix 7 playing an important role in larvicidal activity of the Cry4Ba toxin.     

Association of the components of the binary toxin from Bacillus sphaericus in solution and with model lipid bilayers

We show herein that interaction in aqueous solution of the two components of binary toxin from Bacillus sphaericus, BinA and BinB, leads to a dramatic conformational change, from beta turns or random coil, to beta structure. Also, either BinA or BinB separately or their equimolar mixture, interact with lipid bilayers resulting in further conformational changes. Upon membrane association, the change in conformation observed for BinA or BinB separately is different from that observed when the proteins are combined, indicating that proper folding depends on the presence of the complementary subunit. We also show, in contrast to previous reports, that BinB, but not BinA, is able to insert in model neutral lipid monolayers.     

High-Level Expression in <Emphasis Type="Italic">Escherichia coli</Emphasis>, Purification and Mosquito-Larvicidal Activity of the Binary Toxin from <Emphasis Type="Italic">Bacillus sphaericus</Emphasis>

The mosquito-larvicidal binary toxin produced by Bacillus sphaericus consists of two polypeptides: BinA and BinB. Both proteins function together, and maximum toxicity is obtained when both are present in equimolar ratio. Cloning and expression of each component separately in heterologous hosts led to low toxicity of the crystal proteins. To improve the expression level, the purification process, and the activity of the binary toxin, the binA and binB genes were separately cloned in Eschericia coli. Each gene was fused in frame to the glutathione S-transferase (GST) gene to be expressed as GST-fusion protein (GST-BinA and GST-BinB). A high expression level was observed from both constructs, and the fusion proteins exhibited high toxicity to Culex quinquefasciatus larvae. High-purity toxin could be obtained by affinity chromatography. The result suggests that GST moiety facilitates high protein production and enables better solubility of the toxin inclusions inside the larval gut, leading to higher toxicity of the fusion protein.     

The <Emphasis Type="Italic">C</Emphasis>-Terminal Domain of BinA Is Responsible for <Emphasis Type="Italic">Bacillus</Emphasis> <Emphasis Type="Italic">sphaericus</Emphasis> Binary Toxin BinA–BinB Interaction

The binary toxin (Bin) from Bacillus sphaericus consists of two polypeptides, BinA (42 kDa) and BinB (51 kDa) that work together to kill susceptible mosquito larvae. To investigate the functional regions of BinA involved in the interaction with BinB, four BinA truncated fragments, from both N- and C- termini, were constructed and expressed in Escherichia coli. Neither individual nor a mixture of fragments of BinA showed larvicidal activity against Culex quinquefasciatus larvae even using a high dose of toxins. Far-Western dot blot analysis showed strong binding of both C-terminal fragments (17 and 28 kDa) to BinB protein. This is the first report to demonstrate that the C-terminal part of BinA plays an important role for the interaction with BinB.     

Identification and molecular structural prediction analysis of a toxicity determinant in the Bacillus sphaericus crystal larvicidal toxin.

The operon containing the genes encoding the subunits of the binary crystal toxin of Bacillus sphaericus strain LP1-G, BinA and BinB (41.9 kDa and 51.4 kDa, respectively), was cloned and sequenced. Purified crystals were not toxic to Culex pipiens larvae. Comparison of the amino-acid sequences of this strain (Bin4) with those of the three other known toxin types (Bin1, Bin2 and Bin3) revealed mutations at six positions, including a serine at position 93 of BinA4, whereas all other types of BinA toxin from B. sphaericus had a leucine at this position. Reciprocal site-directed mutagenesis was performed to replace this serine in BinA4 from LP1-G with a leucine and the leucine in the BinA2 protein from strain 1593 with a serine. Native and mutated genes were cloned and overexpressed. Inclusion bodies were tested on C. pipiens larvae. Unlike the native Bin4 toxin, the mutated protein was toxic, and the reciprocal mutation in Bin2 led to a significant loss of toxicity. In vitro receptor-binding studies showed similar binding behaviour for native and mutated toxins. In the absence of any experimental data on the 3D structure of these proteins, sequence analysis and secondary-structure predictions were performed. Amino acid 93 of the BinA polypeptide probably belongs to an alpha helix that is sensitive to amino-acid modifications. Position 93 may be a key element in the formation of the BinA-BinB complex responsible for the toxicity and stability of B. sphaericus Bin toxins.     

Role of tryptophan residues in toxicity of Cry1Ab toxin from Bacillus thuringiensis

Bacillus thuringiensis produces insecticidal proteins (Cry protoxins) during the sporulation phase as parasporal crystals. During intoxication, the Cry protoxins must change from insoluble crystals into membrane-inserted toxins which form ionic pores. The structural changes of Cry toxins during oligomerization and insertion into the membrane are still unknown. The Cry1Ab toxin has nine tryptophan residues; seven are located in domain I, the pore-forming domain, and two are located in domain II, which is involved in receptor recognition. Eight Trp residues are highly conserved within the whole family of three-domain Cry proteins, suggesting an essential role for these residues in the structural folding and function of the toxin. In this work, we analyzed the role of Trp residues in the structure and function of Cry1Ab toxin. We replaced the Trp residues with phenylalanine or cysteine using site-directed mutagenesis. Our results show that W65 and W316 are important for insecticidal activity of the toxin since their replacement by Phe reduced the toxicity against Manduca sexta. The presence of hydrophobic residue is important at positions 117, 219, 226, and 455 since replacement by Cys affected either the crystal formation or the insecticidal activity of the toxin in contrast to replacement by Phe in these positions. Additionally, some mutants in positions 219, 316, and 455 were also affected in binding to brush border membrane vesicles (BBMV). This is the first report that studies the role of Trp residues in the activity of Cry toxins.     

Role of Tryptophan Residues in Toxicity of Cry1Ab Toxin from Bacillus thuringiensis

Bacillus thuringiensis produces insecticidal proteins (Cry protoxins) during the sporulation phase as parasporal crystals. During intoxication, the Cry protoxins must change from insoluble crystals into membrane-inserted toxins which form ionic pores. The structural changes of Cry toxins during oligomerization and insertion into the membrane are still unknown. The Cry1Ab toxin has nine tryptophan residues; seven are located in domain I, the pore-forming domain, and two are located in domain II, which is involved in receptor recognition. Eight Trp residues are highly conserved within the whole family of three-domain Cry proteins, suggesting an essential role for these residues in the structural folding and function of the toxin. In this work, we analyzed the role of Trp residues in the structure and function of Cry1Ab toxin. We replaced the Trp residues with phenylalanine or cysteine using site-directed mutagenesis. Our results show that W65 and W316 are important for insecticidal activity of the toxin since their replacement by Phe reduced the toxicity against Manduca sexta. The presence of hydrophobic residue is important at positions 117, 219, 226, and 455 since replacement by Cys affected either the crystal formation or the insecticidal activity of the toxin in contrast to replacement by Phe in these positions. Additionally, some mutants in positions 219, 316, and 455 were also affected in binding to brush border membrane vesicles (BBMV). This is the first report that studies the role of Trp residues in the activity of Cry toxins.     

Functional roles of Tryptophan residues in diketoreductase from Acinetobacter baylyi

Diketoreductase (DKR) from Acinetobacter baylyi contains two tryptophan residues at positions 149 and 222. Trp-149 and Trp-222 are located along the entry path of substrate into active site and at the dimer interface of DKR, respectively. Single and double substitutions of these positions were generated to probe the roles of tryptophan residues. After replacing Trp with Ala and Phe, biochemical and biophysical characteristics of the mutants were thoroughly investigated. Enzyme activity and substrate binding affinity of W149A and W149F were remarkably decreased, suggesting that Trp-149 regulates the position of substrate at the binding site. Meanwhile, enzyme activity of W222F was increased by 1.7-fold while W222A was completely inactive. In addition to lower thermostability of Trp-222 mutants, molecular modeling of the mutants revealed that Trp-222 is vital to protein folding and dimerization of the enzyme. [BMB Reports 2012; 45(8): 452-457].     

The N-terminal third of the BinB subunit from the Bacillus sphaericus binary toxin is sufficient for its interaction with midgut receptors in Culex quinquefasciatus

Heterodimeric binary (Bin) toxin, the major insecticidal protein from Bacillus sphaericus, acts on Culex quinquefasciatus larvae through specific binding to the midgut receptor Cqm1, a role mediated by its 448-amino-acid-long BinB subunit. The molecular basis for receptor recognition is not well understood and this study attempted to identify protein segments and amino acid motifs within BinB that are required for this event. First, N- and C-terminally truncated constructs were evaluated for their capacity to bind to native Cqm1 through pull-down assays. These showed that residues N33 to L158 of the subunit are required for Cqm1 binding. Nine different full-length mutants were then generated in which selected blocks of three amino acids were replaced by alanines. In new pull-down assays, two mutants, in which residues (85) IRF(87) and (147) FQF(149) were targeted, failed to bind the receptor. Competition binding assays confirmed the requirements for the N-terminal 158 residues, and the (147) FQF(149) epitope, for the mutant proteins to compete with native Bin toxin when binding to membrane fractions from the insect midgut. The data from this work rule out the involvement of C-terminal segments in receptor binding, highlighting the need for multiple elements within the protein's N-terminal third for it to occur.     

Tryptophan scanning mutagenesis in the TM3 domain of the Torpedo californica acetylcholine receptor beta subunit reveals an alpha-helical structure

We used tryptophan substitutions to characterize the beta M3 transmembrane domain (betaTM3) of the acetylcholine receptor (AChR). We generated 15 mutants with tryptophan substitutions within the betaTM3 domain, between residues R282W and I296W. The various mutants were injected into Xenopus oocytes, and expression levels were measured by [125I]-alpha-bungarotoxin binding. Expression levels of the M288W, I289W, L290W, and F293W mutants were similar to that of wild type, whereas the other mutants (R282W, Y283W, L284W, F286W, I287W, V291W, A292W, S294W, V295W, and I296W) were expressed at much lower levels than that of wild type. None of these tryptophan mutants produced peak currents larger than that of wild type. Five of the mutants, L284W, F286W, I287W, V295W, and I296W, were expressed at levels <15% of the wild type. I296W had the lowest expression levels and did not display any significant ACh-induced current, suggesting that this position is important for the function and assembly of the AChR. Tryptophan substitution at three positions, L284, V291, and A292, dramatically inhibited AChR assembly and function. A periodicity analysis of the alterations in AChR expression at positions 282-296 of the betaTM3 domain was consistent with an alpha-helical structure. Residues known to be exposed to the membrane lipids, including R282, M285, I289, and F293, were all found in all the upper phases of the oscillatory pattern. Mutants that were expressed at lower levels are clustered on one side of a proposed alpha-helical structure. These results were incorporated into a structural model for the spatial orientation of the TM3 of the Torpedo californica beta subunit.