Luis Enrique Zavala scite author profile

Background Bacillus thuringiensis Cry toxins, that are used worldwide in insect control, kill insects by a mechanism that depends on their ability to form oligomeric pores that insert into the insect-midgut cells. These toxins are being used worldwide in transgenic plants or spray to control insect pests in agriculture. However, a major concern has been the possible effects of these insecticidal proteins on non-target organisms mainly in ecosystems adjacent to agricultural fields.Methodology/Principal FindingsWe isolated and characterized 11 non-toxic mutants of Cry1Ab toxin affected in different steps of the mechanism of action namely binding to receptors, oligomerization and pore-formation. These mutant toxins were analyzed for their capacity to block wild type toxin activity, presenting a dominant negative phenotype. The dominant negative phenotype was analyzed at two levels, in vivo by toxicity bioassays against susceptible Manduca sexta larvae and in vitro by pore formation activity in black lipid bilayers. We demonstrate that some mutations located in helix α-4 completely block the wild type toxin activity at sub-stoichiometric level confirming a dominant negative phenotype, thereby functioning as potent antitoxins.Conclusions/SignificanceThis is the first reported case of a Cry toxin dominant inhibitor. These data demonstrate that oligomerization is a fundamental step in Cry toxin action and represent a potential mechanism to protect special ecosystems from the possible effect of Cry toxins on non-target organisms.

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Domains II and III of Bacillus thuringiensis Cry1Ab Toxin Remain Exposed to the Solvent after Insertion of Part of Domain I into the Membrane

Zavala¹,

Pardo-López²,

Cantón

et al. 2011

Journal of Biological Chemistry

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Bacillus thuringiensis produces insecticidal proteins named Cry toxins, that are used commercially for the control of economical important insect pests. These are pore-forming toxins that interact with different receptors in the insect gut, forming pores in the apical membrane causing cell burst and insect death. Elucidation of the structure of the membrane-inserted toxin is important to fully understand its mechanism of action. One hypothesis proposed that the hairpin of ␣-helices 4 -5 of domain I inserts into the phospholipid bilayer, whereas the rest of helices of domain I are spread on the membrane surface in an umbrella-like conformation. However, a second hypothesis proposed that the three domains of the Cry toxin insert into the bilayer without major conformational changes. In this work we constructed single Cys Cry1Ab mutants that remain active against Manduca sexta larvae and labeled them with different fluorescent probes that have different responses to solvent polarity. Different soluble quenchers as well as a membranebound quencher were used to compare the properties of the soluble and brush border membrane-inserted forms of Cry1Ab toxin. The fluorescence and quenching analysis presented here, revealed that domains II and III of the toxin remain in the surface of the membrane and only a discrete region of domain I is inserted into the lipid bilayer, supporting the umbrella model of toxin insertion.

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Correction: Dominant Negative Mutants of Bacillus thuringiensis Cry1Ab Toxin Function as Anti-Toxins: Demonstration of the Role of Oligomerization in Toxicity

RodrÃguez-AlmazÃ¡n¹,

Zavala²,

MuÃ±oz-Garay³

et al. 2013

PLoS ONE

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Background: Bacillus thuringiensis Cry toxins, that are used worldwide in insect control, kill insects by a mechanism that depends on their ability to form oligomeric pores that insert into the insect-midgut cells. These toxins are being used worldwide in transgenic plants or spray to control insect pests in agriculture. However, a major concern has been the possible effects of these insecticidal proteins on non-target organisms mainly in ecosystems adjacent to agricultural fields.Methodology/Principal Findings: We isolated and characterized 11 non-toxic mutants of Cry1Ab toxin affected in different steps of the mechanism of action namely binding to receptors, oligomerization and pore-formation. These mutant toxins were analyzed for their capacity to block wild type toxin activity, presenting a dominant negative phenotype. The dominant negative phenotype was analyzed at two levels, in vivo by toxicity bioassays against susceptible Manduca sexta larvae and in vitro by pore formation activity in black lipid bilayers. We demonstrate that some mutations located in helix a-4 completely block the wild type toxin activity at sub-stoichiometric level confirming a dominant negative phenotype, thereby functioning as potent antitoxins.Conclusions/Significance: This is the first reported case of a Cry toxin dominant inhibitor. These data demonstrate that oligomerization is a fundamental step in Cry toxin action and represent a potential mechanism to protect special ecosystems from the possible effect of Cry toxins on non-target organisms.

show abstract

Domains II and III of Bacillus thuringiensis Cry1Ab toxin remain exposed to the solvent after insertion of part of domain I into the membrane.

Zavala¹,

Pardo-López²,

Cantón³

et al. 2012

Journal of Biological Chemistry

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PAGE 19111:An error has been detected in the methodology description of "Insertion of Cry1Ab Mutant Toxin into the BBMV." The samples used in Western blot assays were not boiled. Instead, they were incubated for 5 min at 37°C before loading into 10% SDS-PAGE. A new supplemental Fig. S1 is presented. FIGURE S1. Western blot analysis of membrane associated proteins. Mutant proteins were incubated with BBMV at pH 9.0. Toxin proteins inserted into the BBMV were recovered by centrifugation. Pellets were suspended in Laemmli sample buffer, incubated 5 min at 37°C, loaded into 10% SDS-PAGE, and analyzed by Western blot using polyclonal anti-Cry1Ab antibody and a secondary goat anti-rabbit HRP antibody. The membrane pellet showed that all proteins form oligomeric structures when incubated with Manduca sexta BBMV.

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