4.5 Article

Can membrane composition traffic toxins? Mycolactone and preferential membrane interactions

期刊

BIOPHYSICAL JOURNAL
卷 121, 期 22, 页码 4260-4270

出版社

CELL PRESS
DOI: 10.1016/j.bpj.2022.10.019

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资金

  1. National Institute of General Medicine of the National Institutes of Health [R35GM143117]
  2. National Science Foundation [ACI-1548562]
  3. Center for High Performance Computing at the University of Utah [MCB200018]

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This study investigates the association and permeation of Mycolactone through models of the mammalian endoplasmic reticulum (ER) and plasma membranes (PMs). The research reveals that Mycolactone exhibits different binding and permeation mechanisms in the ER membrane compared to the PMs. Increased order and interactions with unsaturated lipid tails stabilize the toxin in the ER membrane, while disruption of lipid packing destabilizes it in the PMs.
Mycolactone is a cytotoxic and immunosuppressive macrolide produced by Mycobacterium ulcerans and the sole causative agent of the neglected tropical skin disease Buruli ulcer. The toxin acts by invading host cells and interacting with intracellular targets to disrupt multiple fundamental cellular processes. Mycolactone's amphiphilic nature enables strong interactions with lipophilic environments, including cellular membranes; however, the specificity of these interactions and the role of membranes in the toxin's pathogenicity remain unknown. It is likely that preferential interactions with lipophilic carriers play a key role in the toxin's distribution in the host, which, if understood, could provide insights to aid in the development of needed diagnostics for Buruli ulcer disease. In this work, molecular dynamics simulations were combined with enhanced free-energy sampling to characterize mycolactone's association with and permeation through models of the mammalian endoplasmic reticulum (ER) and plasma membranes (PMs). We find that increased order in the PMs not only leads to a different permeation mechanism compared with that in the ER membrane but also an energetic driving force for ER localization. Increased hydration, membrane deformation, and preferential interactions with unsaturated lipid tails stabilize the toxin in the ER membrane, while disruption of lipid packing is a destabilizing force in the PMs.

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