Effect of cholesterol on the mechanical stability of gel-phase phospholipid bilayers studied by AFM force spectroscopy

TL;DR

This study investigates how cholesterol influences the mechanical stability of phospholipid bilayers, revealing that cholesterol weakens bilayer stability, which has implications for joint lubrication and membrane biophysics.

Contribution

It provides a systematic AFM-based analysis of cholesterol's effect on bilayer stability across different lipids, conditions, and experimental parameters, highlighting its weakening role.

Findings

Cholesterol decreases bilayer stability in both DSPC and DPPC.

Salt enhances the mechanical stability of lipid bilayers.

Experimental parameters like tip radius and loading rate do not significantly affect breakthrough forces.

Abstract

The low sliding friction of articular cartilage in the major joints , which is crucial for its homeostasis and for joint health, has been attributed to lipid bilayers forming lubricious boundary layers at its surface. The robustness of such layers, and thus their lubrication efficiency at joint pressures, depends on the lipids forming them, including cholesterol, which may act to strengthen of weaken the bilayer. A systematic study using an Atomic Force Microscope (AFM) was carried out to understand the effect of cholesterol on the nanomechanical stability of two saturated phospholipids, DSPC (1,2-distearoyl-sn-glycero-3-phosphatidlycholine) and DPPC (1,2-dipalmitoyl-sn-glycero-phosphatidylcholine), that differ in acyl chain lengths. Measurements were carried out both in water and in phosphate buffer solution (PBS). The nanomechanical stability of the lipid bilayers was quantitatively evaluated by measuring the breakthrough force needed to puncture the bilayer by the AFM tip. The molar fractions of cholesterol incorporated in the bilayers were 10% and 40%. We found that for both DSPC and DPPC, cholesterol significantly decreases the mechanical stability of the bilayers in solid ordered (SO) phase. In accordance with the literature, the strengthening effect of salt on the lipid bilayers was also observed. For DPPC with 10 mol % cholesterol, the effect of tip properties and the experimental procedure parameters on the breakthrough forces were also studied. Tip radius (2 - 42 nm), material (Si, Si3N4, Au) and loading rate (40 - 1000 nm/s) were varied systematically. The values of the breakthrough forces measured were not significantly affected by any of these parameters, showing that the weakening effect of cholesterol does not result from such changes in experimental conditions. This study helps to shed light on the mechanism of physiological lubrication.