The membrane interaction of dynorphin A depends on lipid head-group charge
(English)Manuscript (preprint) (Other academic)
The influence of lipid bicelles on the dynamics of the opioid peptide DynA has been investigated by Nuclear Magnetic Resonance. DynA exerts its opioid effects mainly through interactions with the κ subtype of the opioid receptors, but has also been demonstrated to have direct interactions with membranes. Among other properties, it has been shown that the peptide causes membrane disruption and may penetrate bilayers. Despite the fact that DynA appears to bind tightly to model lipid bilayers, no structure induction has been observed. To further study the effect of membrane interactions we have here therefore measured the fast local dynamics of DynA specifically labeled with 15N in three backbone amide sites (Gly2, Leu5 and Leu12) in fast-tumbling bicelles, both with and without the incorporation of the negatively charged dimyristoylglycerol. We also examined the amide exchange in the two bicelles. We find that despite the fact that DynA is largely unstructured in both types of bicelles, the peptide has restricted backbone dynamics, which depends on the presence of negatively charged lipids. Moreover we see that the lipid dependence is not uniform throughout the sequence, but is most noticeable for Leu5, which precedes an unusually basic stretch of amino acid residues. The findings indicate that this basic sequence may be of significance for bilayer recognition. Finally, we note that the dynamical behavior of the peptide is much more influenced by the lipid surroundings than what the structural properties are.
Research subject Biophysics
IdentifiersURN: urn:nbn:se:su:diva-107825OAI: oai:DiVA.org:su-107825DiVA: diva2:750689