Abstract
Pore-forming toxins constitute a class of potent virulence factors that attack their host membrane in a two- or three-step mechanism. After binding to the membrane, often aided by specific receptors, they form pores in the membrane. Pore formation either unfolds a cytolytic activity in itself or provides a pathway to introduce enzymes into the cells that act upon intracellular proteins. The elucidation of the pore-forming mechanism of many of these toxins represents a major research challenge. As the toxins often refold after entering the membrane, their structure in the membrane is unknown, and key questions such as the stoichiometry of individual pores and their mechanism of oligomerization remain unanswered. In this study, we used single subunit counting based on fluorescence spectroscopy to explore the oligomerization process of the Cry1Aa toxin of Bacillus thuringiensis. Purified Cry1Aa toxin molecules labeled at different positions in the pore-forming domain were inserted into supported lipid bilayers, and the photobleaching steps of single fluorophores in the fluorescence time traces were counted to determine the number of subunits of each oligomer. We found that toxin oligomerization is a highly dynamic process that occurs in the membrane and that tetramers represent the final form of the toxins in a lipid bilayer environment.
Highlights
The stoichiometry of pore-forming toxins is frequently unknown because crystal structures do not reflect the active conformations
The measurement of the efficiency of labeling (EOL) at 0.76 Ϯ 0.02 established that not more than one fluorophore was attached to each monomer, meaning that each photobleaching event corresponds to a single subunit (Fig. 1D)
We used fluorescence spectroscopy based on the stepwise photobleaching principle to count the number of subunits present in Cry1Aa toxin pores within a supported bilayer free of toxin receptors
Summary
The stoichiometry of pore-forming toxins is frequently unknown because crystal structures do not reflect the active conformations. Results: We used single subunit counting on fluorescently labeled Cry1Aa toxin of Bacillus thuringiensis to follow its oligomerization process. As the toxins often refold after entering the membrane, their structure in the membrane is unknown, and key questions such as the stoichiometry of individual pores and their mechanism of oligomerization remain unanswered. We used single subunit counting based on fluorescence spectroscopy to explore the oligomerization process of the Cry1Aa toxin of Bacillus thuringiensis. Purified Cry1Aa toxin molecules labeled at different positions in the pore-forming domain were inserted into supported lipid bilayers, and the photobleaching steps of single fluorophores in the fluorescence time traces were counted to determine the number of subunits of each oligomer. We found that toxin oligomerization is a highly dynamic process that occurs in the membrane and that tetramers represent the final form of the toxins in a lipid bilayer environment
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