Abstract

Oligomers of pneumolysin form transmembrane channels in cholesterol-containing lipid bilayers. The mechanism of pore formation involves a multistage process in which the protein, at first, assembles into a ring-shaped complex on the outer-bilayer leaflet. In a subsequent step, the complex inserts into the membrane. Contrary to most investigations of pore formation that have focussed on protein changes, we have deduced how the lipid-packing order is altered in different stages of the pore-forming mechanism. An optical tweezing apparatus was used, in combination with microfluidics, to isolate large-unilamellar vesicles and control exposure of the bilayer to pneumolysin. By monitoring Raman-scattered light from a single-trapped liposome, the effect of the protein on short-range order and rotational diffusion of lipids could be inferred from changes in the envelope of the C–H stretch. A significant change in the lipid-packing order takes place during assembly of pre-pore oligomers. We were not able to detect a change in the lipid-packing order during the initial stage of protein binding, or any further change during the insertion of oligomers. Pre-pore complexes induce a transformation in which a bilayer, resembling a liquid-ordered phase is changed into a bilayer resembling a fluid-liquid-disordered phase surrounding ordered microdomains enriched in cholesterol and protein complexes.

Highlights

  • A bespoke microscope apparatus was used for optical tweezing and the measurement of Raman spectra from trapped unilamellar vesicles

  • A photomask containing negative images of the pattern of microfluidic channels was reproduced at 128,000 dpi on a chrome layer supported on 0.060′′-thick soda lime (JD Photo-Tools Inc.)

  • The master template was fabricated by spin coating (500 rpm, 30 s, followed by 1500 rpm, 30 s) a permanent epoxy negative photoresist (SU-8 2050, MicroChem Corp.) onto the polished surface of a 2′′-diameter boron-doped silicon substrate ({100} plane, 280 μm-thickness; MicroChemical GmbH)

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Summary

Introduction

Wild-type PLY, D4 and selected mutants (D205R, T304R and N339R), were incubated with unilamellar liposomes (1:1 POPC/chol). A bespoke microscope apparatus was used for optical tweezing and the measurement of Raman spectra from trapped unilamellar vesicles. Spectroscopic measurements were made by focussing a continuous-wave 488 nm laser (3 mW) onto the optically-trapped particle and collecting the inelastic-scattered light.

Results
Conclusion

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