Insecticidal crystal proteins of Bacillus thuringiensis.

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Microbiol Mol Biol Rev. 1989 June; 53(2): 242-255

Insecticidal crystal proteins of Bacillus thuringiensis.

H Höfte and H R Whiteley

SUMMARY

A classification for crystal protein genes of Bacillus thuringiensisis presented. Criteria used are the insecticidal spectra andthe amino acid sequences of the encoded proteins. Fourteen genesare distinguished, encoding proteins active against either Lepidoptera(cryI), Lepidoptera and Diptera (cryII), Coleoptera (cryIII),or Diptera (cryIV). One gene, cytA, encodes a general cytolyticprotein and shows no structural similarities with the othergenes. Toxicity studies with single purified proteins demonstratedthat every described crystal protein is characterized by a highlyspecific, and sometimes very restricted, insect host spectrum.Comparison of the deduced amino acid sequences reveals sequenceelements which are conserved for Cry proteins. The expressionof crystal protein genes is affected by a number of factors.Recently, two distinct sigma subunits regulating transcriptionduring different stages of sporulation have been identified,as well as a protein regulating the expression of a crystalprotein at a posttranslational level. Studies on the biochemicalmechanisms of toxicity suggest that B. thuringiensis crystalproteins induce the formation of pores in membranes of susceptiblecells. In vitro binding studies with radiolabeled toxins demonstrateda strong correlation between the specificity of B. thuringiensistoxins and the interaction with specific binding sites on theinsect midgut epithelium. The expression of B. thuringiensiscrystal proteins in plant-associated microorganisms and in transgenicplants has been reported. These approaches are potentially powerfulstrategies for the protection of agriculturally important cropsagainst insect damage.

Microbiol Mol Biol Rev. 1989 June; 53(2): 242-255

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