Abstract
After endocytic uptake by mammalian cells, the heterodimeric plant toxin ricin is transported to the endoplasmic reticulum (ER), where the ricin A chain (RTA) must cross the ER membrane to reach its ribosomal substrates. Here, using gel filtration chromatography, sedimentation, fluorescence, fluorescence resonance energy transfer, and circular dichroism, we show that both fluorescently labeled and unlabeled RTA bind both to ER microsomal membranes and to negatively charged liposomes. The binding of RTA to the membrane at 0-30 °C exposes certain RTA residues to the nonpolar lipid core of the bilayer with little change in the secondary structure of the protein. However, major structural rearrangements in RTA occur when the temperature is increased. At 37 °C, membrane-bound toxin loses some of its helical content, and its C terminus moves closer to the membrane surface where it inserts into the bilayer. RTA is then stably bound to the membrane because it is nonextractable with carbonate. The sharp temperature dependence of the structural changes does not coincide with a lipid phase change because little change in fluorescence-detected membrane mobility occurred between 30 and 37 °C. Instead, the structural rearrangements may precede or initiate toxin retrotranslocation through the ER membrane to the cytosol. The sharp temperature dependence of these changes in RTA further suggests that they occur optimally in mammalian targets of the plant toxin.
Highlights
We show, using chromatography, fluorescence spectroscopy and circular dichroism, that RTA binds to such bilayers in a temperature-independent manner but that the physiologically relevant temperature of 37 °C is required for specific changes in toxin structure and exposure to the nonpolar lipid core
Because RTA is released from RTB within the lumen of the endoplasmic reticulum (ER), it is conceivable that RTA binds or even inserts into the ER membrane during its passage from the lumen to the cytosol
NBD has a relatively small size for a dye, it is uncharged, it has sufficient polar character to be soluble in an aqueous milieu, and it is not so hydrophobic that it aggressively buries itself in the nonpolar interior of a membrane
Summary
One possibility is that the hydrophobic C terminus of RTA [28], newly exposed following reduction and dissociation of RTB [3], may directly promote the kind of chaperone interaction that leads to membrane translocation This region may trigger membrane lipid interactions in a process that induces specific or random structural change in the toxin. A previous study has shown that upon mixing RTA with liposomes containing a negatively charged phospholipid (POPG), the toxin underwent major structural changes while bound to the bilayer and was rendered sensitive to protease [29] This suggestive result led us to examine the interaction of RTA with liposomes containing phosphatidylserine (POPS), a negatively charged lipid that, in contrast to POPG, is a significant component of biological membranes [30]. The implications of these findings for RTA retrotranslocation are discussed
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