Abstract
Bacillus thuringiensis subsp. israelensis produces crystal inclusions composed of three-domain Cry proteins and cytolytic Cyt toxins, which are toxic to different mosquito larvae. A key component is the Cyt toxin, which synergizes the activity of the other Cry toxins, thereby resulting in high toxicity. The precise mechanism of action of Cyt toxins is still debated, and two models have been proposed: the pore formation model and the detergent effect. Here, we performed a systematic structural characterization of the Cyt toxin interaction with different membranes, including in Aedes aegypti larval brush border membrane vesicles, small unilamellar vesicle liposomes, and rabbit erythrocytes. We examined Cyt1Aa insertion into these membranes by analyzing fluorescence quenching in solution and in the membrane-bound state. For this purpose, we constructed several Cyt1Aa variants having substitutions with a single cysteine residue in different secondary structures, enabling Cys labeling with Alexa Fluor 488 for quenching analysis using I-soluble quencher in solution and in the membrane-bound state. We identified the Cyt1Aa residues exposed to the solvent upon membrane insertion, predicting a possible topology of the membrane-inserted toxin in the different membranes. Moreover, toxicity assays with these variants revealed that Cyt1Aa exerts its insecticidal activity and hemolysis through different mechanisms. We found that Cyt1Aa exhibits variable interactions with each membrane system, with deeper insertion into mosquito larva membranes, supporting the pore formation model, whereas in the case of erythrocytes and small unilamellar vesicles, Cyt1Aa's insertion was more superficial, supporting the notion that a detergent effect underlies its hemolytic activity.
Highlights
Bacillus thuringiensis subsp. israelensis (Bti) is the active component of many larvicidal products used worldwide for mosquito control such as Aedes aegypti, Anopheles spp., and Culex spp
The key component is the Cyt toxin that synergizes the activity of the Cry toxins present in the crystal, and it is able to overcome the resistance of mosquito populations against individual Cry or multiple Cry toxins [6, 8]
Bti Cyt1Aa toxin is a versatile protein that has proven to be toxic to different insect orders and to erythrocytes and some mammalian cell lines [7, 14,15,16,17]
Summary
Bacillus thuringiensis subsp. israelensis (Bti) is the active component of many larvicidal products used worldwide for mosquito control such as Aedes aegypti, Anopheles spp., and Culex spp. The larvicidal activity of Bti is due to the insecticidal toxins found in parasporal inclusions that are formed during the sporulation growth phase These parasporal crystals are composed of different kinds of d-endotoxins such as the three-domain Cry proteins (Cry4Aa, Cry4Ba, Cry10Aa, and Cry11Aa) and cytolytic toxins (Cyt1Aa, Cyt2Ba, and Cyt1Ca) [5]. The absence of Bti-resistant mosquitoes is principally due to the multiple mechanisms of action displayed by these toxins and to their synergism [6, 7]. It was proposed that Cyt1Aa synergizes the toxicity of Cry toxins such as Cry11Aa or Cry4Ba, by functioning as a receptor that facilitates their oligomerization These Cry oligomeric structures are prone to interact with additional receptors and insert into the membrane killing the mosquito larvae [9,10,11]. In the pore formation model, it was proposed that the b-sheet region of Cyt1Aa
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