1. Large‐Peptide Permeation Through a Membrane Channel: Understanding Protamine Translocation Through CymA from Klebsiella Oxytoca **
- Author
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Jayesh Arun Bafna, Ulrich Kleinekathöfer, Jigneshkumar Dahyabhai Prajapati, Mohamed Nilam, Mathias Winterhalter, Sushil Pangeni, and Werner M. Nau
- Subjects
Models, Molecular ,endocrine system ,Kinetics ,Peptide ,010402 general chemistry ,01 natural sciences ,Catalysis ,Ion Channels ,Protamines ,Reversal potential ,Research Articles ,chemistry.chemical_classification ,Liposome ,biology ,010405 organic chemistry ,Klebsiella oxytoca ,Cytochromes c ,Biological Transport ,General Chemistry ,molecular dynamics simulations ,Permeation ,electrophysiology ,Protamine ,0104 chemical sciences ,outer membrane porins ,Membrane ,chemistry ,biology.protein ,Biophysics ,Membrane channel ,membrane translocation assay ,Membrane Channels | Hot Paper ,protamine ,Research Article - Abstract
Quantifying the passage of the large peptide protamine (Ptm) across CymA, a passive channel for cyclodextrin uptake, is in the focus of this study. Using a reporter‐pair‐based fluorescence membrane assay we detected the entry of Ptm into liposomes containing CymA. The kinetics of the Ptm entry was independent of its concentration suggesting that the permeation through CymA is the rate‐limiting factor. Furthermore, we reconstituted single CymA channels into planar lipid bilayers and recorded the ion current fluctuations in the presence of Ptm. To this end, we were able to resolve the voltage‐dependent entry of single Ptm peptide molecules into the channel. Extrapolation to zero voltage revealed about 1–2 events per second and long dwell times, in agreement with the liposome study. Applied‐field and steered molecular dynamics simulations added an atomistic view of the permeation events. It can be concluded that a concentration gradient of 1 μm Ptm leads to a translocation rate of about one molecule per second and per channel., Surprisingly, large peptides (Protamine, 5.1 kDa) can permeate through bacterial outer membrane channels. The use of fluorescence, electrophysiology, and all‐atom modeling allows to quantify the flux. This approach can be transferred to related problems.
- Published
- 2021