Towards the application of Tc toxins as a universal protein translocation system

Tc toxins are bacterial protein complexes that inject cytotoxic enzymes into target cells using a syringe-like mechanism. Tc toxins are composed of a membrane translocator and a cocoon that encapsulates a toxic enzyme. The toxic enzyme varies between Tc toxins from different species and is not conserved. Here, we investigate whether the toxic enzyme can be replaced by other small proteins of different origin and properties, namely Cdc42, herpes simplex virus ICP47, Arabidopsis thaliana iLOV, Escherichia coli DHFR, Ras-binding domain of CRAF kinase, and TEV protease. Using a combination of electron microscopy, X-ray crystallography and in vitro translocation assays, we demonstrate that it is possible to turn Tc toxins into customizable molecular syringes for delivering proteins of interest across membranes. We also infer the guidelines that protein cargos must obey in terms of size, charge, and fold in order to apply Tc toxins as a universal protein translocation system.

Gelatinase Is Important for Translocation of Enterococcus faecalis across Polarized Human Enterocyte-Like T84 Cells

ABSTRACT Previously, in our laboratory, we established a two-chamber system to study translocation of Enterococcus faecalis across monolayers of polarized human colon carcinoma-derived T84 cells. By using the same system in the present study, we now show that disruption of gelE of strain OG1RF, which also has a polar effect on the cotranscribed sprE, as well as disruption of its regulatory system (fsrA, fsrB, and fsrC) resulted in a loss of detectable translocation by E. faecalis OG1RF; these mutants lost gelatinase (GelE) and serine protease (SprE) production by standard assay. A gelE deletion mutant of OG1RF (GelE− SprE+) also showed that significantly reduced translocation and complementation with the gelE gene (pTEX5438) in trans restored gelatinase and translocation, demonstrating that gelatinase is important for E. faecalis translocation. Complementation of fsrA, fsrB, and fsrC mutants with all three fsr genes also resulted in production of gelatinase and translocation. Furthermore, introduction of fsr genes into two non-gelatinase-producing E. faecalis isolates, the well-characterized laboratory strain JH2-2 and a human-derived fecal isolate, TX1322 (both of which have gelE but not fsrA or fsrB, are gelatinase negative, and do not translocate), resulted in gelatinase production by these strains and restored translocation across T84 monolayers, while transformation with pTEX5438 (gelE) showed little or no translocation and no detectable gelatinase, confirming the importance of both fsr and gelatinase for E. faecalis translocation. The importance of gelatinase production was also corroborated among 20 E. faecalis human isolates (7 fecal, 7 endocarditis, and 6 urine isolates), which showed translocation by all gelatinase-positive isolates but little to no translocation for gelatinase nonproducers. These results indicate that gelatinase is important for the successful in vitro translocation of E. faecalis across human enterocyte-like T84 cells.

The motile beta/IC1 subunit of sea urchin sperm outer arm dynein does not form a rigor bond.

We used in vitro translocation and cosedimentation assays to study the microtubule binding properties of sea urchin sperm outer arm dynein and its beta/IC1 subunit. Microtubules glided on glass-absorbed sea urchin dynein for a period of time directly proportional to the initial MgATP2- concentration and then detached when 70-95% of the MgATP2- was hydrolyzed. Detachment resulted from MgATP2- depletion, because (a) perfusion with fresh buffer containing MgATP2- reconstituted binding and gliding, (b) microtubules glided many minutes with an ATP-regenerating system at ATP concentrations which alone supported gliding for only 1-2 min, and (c) microtubules detached upon total hydrolysis of ATP by an ATP-removal system. The products of ATP hydrolysis antagonized binding and gliding; as little as a threefold excess of ADP/Pi over ATP resulted in complete loss of microtubule binding and translocation by the beta/IC1 subunit. In contrast to the situation with sea urchin dynein, microtubules ceased gliding but remained bound to glass-absorbed Tetrahymena outer arm dynein when MgATP2- was exhausted. Cosedimentation assays showed that Tetrahymena outer arm dynein sedimented with microtubules in an ATP-sensitive manner, as previously reported (Porter, M.E., and K. A. Johnson. J. Biol. Chem. 258: 6575-6581). However, the beta/IC1 subunit of sea urchin dynein did not cosediment with microtubules in the absence of ATP. Thus, this subunit, while capable of generating motility, lacks both structural and rigor-type microtubule binding.