Delineation of the toxin coding fragments and an insect-specificity region of a dual toxicity Bacillus thuringiensis crystal protein gene

A series of deletion mutants have been constructed from the dual toxicity Bacillus thuringiensis aizawai IC1 (Bta IC1) crystal protein gene. The mutant toxin genes were expressed in Escherichia coli, their protein products purified and the authenticity of these mutant proteins confirmed immunologically. Analysis of the toxicity spectra of these mutants revealed that lepidopteran toxicity is located on the N-terminal region of the toxin between residues Ile30-Glu595. 3' deletion of a further 37 residues from Glu595 of the lepidopteran-specific toxin abolished lepidopteran toxicity but the resulting protein consisting of residues Ile30-Gly558 was still fully toxic to dipteran larvae and cells. Another mutant crystal protein gene truncated to encode residues between Ile30-Gly563 was toxic only to diptera. These data indicate that the determinants of lepidopteran specificity in the Bta IC1 toxin are located between residues Gly558-Glu595 and that the N-terminal portion of the toxin between Ile30-Gly558 is sufficient to express dipteran toxicity.     

Contribution of the individual components of the δ-endotoxin crystal to the mosquitocidal activity of Bacillus thuringiensis subsp. israelensis

Abstract A glycine-histidine tag (Gly₃His₆) was added to the C-terminus of a fusion protein consisting of the cholera toxin B-subunit (CtxB) and the IgA protease β-domain (Iga β). The aim was to facilitate single-step purification and to create a suitable tool for kinetic and structural studies on Iga β-driven protein translocation across the outer membrane of Gram-negative bacteria. We demonstrate that the glycine-histidine tag does not interfere with the assembly of Iga β in the outer membrane and that the translocator function of the modified Iga β is maintained. The applicability of the new construct for the dissection of the Iga β mediated translocation process and general aspects of C-terminal histidine tagging of outer membrane proteins are discussed.     

Use of an operon fusion to induce expression and crystallisation of a Bacillus thuringiensis δ-endotoxin encoded by a cryptic gene

A δ-endotoxin gene previously cloned from Bacillus thuringiensis subsp. galleriae has been shown by a combination of restriction mapping and DNA sequence analysis to be a cryIIB clone; in common with other cryIIB genes it was found to lack a functional promoter. Addition of a promoter resulted in expression of the gene in Bacillus thuringiensis but did not result in the formation of the crystalline inclusions normally associated with such toxins. Inclusion formation was only observed when the gene was incorporated into an operon containing a gene known to be involved in the crystallisation of another δ-endotoxin.     

Cytotoxicity of a cloned Bacillus thuringiensis subsp. israelensis CryIVB toxin to an Aedes aegypti cell line

A cloned CryIVB toxin was purified from a cured strain of Bacillus thuringiensis (BT) containing the cryIVB gene on the recombinant plasmid Cam135. Solubilized protoxin was treated with Aedes gut extract or trypsin for varying times and tested for toxicity in vitro on three dipteran and one lepidopteran cell line. Treatment with the Aedes extract but not trypsin, produced an active toxin which lysed only Aedes aegypti cells out of those tested. This activation was time-dependent reaching a maximum after 6 h. Both the Aedes extract-treated and trypsin-treated toxin killed A. aegypti larvae, but this toxicity declined rapidly with increasing time of exposure to the proteolytic preparations.     

Involvement of a possible chaperonin in the efficient expression of a cloned CryllA δ-endotoxin gene in Bacillus thuringiensis

The Bacillus thuringiensis cryIIA delta-endotoxin gene is found as the third-gene in a three-gene operon, with a sporulation-dependent promoter lying upstream of the first gene, orf1. We show here that the polypeptide product of the middle gene (orf2) is required for efficient expression of the toxin gene. In the absence of a functional ORF2 polypeptide the toxin does not form the crystalline inclusions characteristic of other known Bacillus thuringiensis toxins. We discuss the importance of this finding with respect to the possible role of chaperonins in the crystallization of these proteins.     

How to kill a mocking bug?

All metazoans have evolved means to protect themselves from threats present in the environment: injuries, viruses, fungi, bacteria and other parasites. Insect protection includes innate physical barriers and both cellular and humoral responses. The insect innate immune response, best characterized in Drosophila melanogaster, is a rapid broad response, triggered by pathogen-associated molecular patterns (PAMPs) recognition, which produces a limited range of effectors that does not alter upon continued pathogen exposure and lacks immunological memory. The Drosophila response, particularly its humoral response, has been investigated by both low and high-throughput methods. Three signalling pathways conserved between insects and mammals have been implicated in this response: Toll (equivalent to mammalian TLR), Imd (equivalent to TNFalpha) and Hop (equivalent to JAK/STAT). This review provides an entry point to the insect immune system literature outlining the main themes in D. melanogaster bacterial pathogen detection and humoral and cellular immune responses. The Drosophila immune response is compared with other insects and the mammalian immune system.     

Structure-function relationships of a membrane pore forming toxin revealed by reversion mutagenesis

Cyt2Aa1 is a haemolytic membrane pore forming toxin produced by Bacillus thuringiensis subsp. kyushuensis. To investigate membrane pore formation by this toxin, second-site revertants of an inactive mutant toxin Cyt2Aa1-I150A were generated by random mutagenesis using error-prone PCR. The decrease in side chain length caused by the replacement of isoleucine by alanine at position 150 in the αD-β4 loop results in the loss of important van der Waals contacts that exist in the native protein between I150 and K199 and L203 on αE. 28 independent revertants of I150A were obtained and their relative toxicity can be explained by the position of the residue in the structure and the effect of the mutation on side-chain interactions. Analysis of these revertants revealed that residues on αA, αB, αC, αD and the loops between αA and αB, αD and β5, β6 and β7 are important in pore formation. These residues are on the surface of the molecule suggesting that they may participate in membrane binding and toxin oligomerization. Changing the properties of the amino acid side-chains of these residues could affect the conformational changes required to transform the water-soluble toxin into the membrane insertion competent state.