Multi-state kinetics of the syringe-like injection mechanism of Tc toxins

Tc toxins are virulence factors of many insects and human pathogenic bacteria. They attach as soluble prepores to receptors on host cells and following acidification in the late endosome, perforate the cell membrane like a syringe to translocate toxic enzymes into the host cell through their pore-forming channel. Although this complex transformation has been structurally well studied, the functional aspects of this large-scale rearrangement, such as the reaction pathway with possible intermediate states and the resulting temporal evolution have remained elusive. Here, we used an integrated biophysical approach to monitor the prepore-to-pore transition and found that it takes ~28 h when induced by high pH in the absence of other factors. In the presence of liposomes, an increasingly high pH or receptors, such as heparin or Vsg, the probability to transform prepores to pores increases by a factor of up to 4. This effect can also be mimicked by biotinylation or site-directed mutagenesis of the shell, demonstrating that shell destabilization is a crucial step in prepore-to-pore transition. We show that shell opening is a heterogeneous process with transition times ranging from 60 ms to 1.6 s and resolve three sequential intermediate states: an initial transient intermediate during shell destabilization, a first stable intermediate where the receptor-binding domains on the shell rearrange and a second stable intermediate with an open shell. In contrast, the ejection of the pore-forming channel from the open shell is highly cooperative with a transition time of < 60 ms. This detailed knowledge of the Tc toxin mechanism of action, even in the absence of receptors, is important for the future application of Tc toxins as biomedical devices or biopesticides. ### Competing Interest Statement The authors have declared no competing interest.