A DSC and FTIR spectroscopic study of the effects of the epimeric coprostan-3-ols and coprostan-3-one on the thermotropic phase behaviour and organization of dipalmitoylphosphatidylcholine bilayer membranes: Comparison with their 5-cholesten analogues

• Cholesterol-like effects on DPPC bilayers decrease in the order 3β-ol > 3α-ol > 3-keto.
• Polar group variations produce greater effects in the cholesterol than in the coprostanol series.
• The cholesterol series is more effective at ordering DPPC bilayers than the coprostanol series.
• The lesser effectiveness of the coprostanol series is due to the inverted ring A/B junction.
• A double bond located at Δ5 is required for maximum solubility in DPPC bilayers.

We present the results of a comparative differential calorimetric and Fourier transform infrared spectroscopic study of the effect of cholesterol and five analogues on the thermotropic phase behaviour and organization of dipalmitoylphosphatidylcholine bilayer membranes. These sterols/steroids differ in both the nature and stereochemistry of the polar head group at C3 (β-OH, α-OH or CO) and in the presence or absence of a double bond in ring B and in the orientation of rings A and B. The Δ5 sterols/steroid have a trans rather than a cis ring A/B junction, and the concentration of these compounds required to abolish the DPPC pretransition, inversely related to their relative ability to disorder gel state DPPC bilayers, decreases in the order β-OH > α-OH > CO. However, in the saturated ring junction-inverted (cis) series, these concentrations are much more similar, regardless of polar head group chemical structure. Similarly, the residual enthalpy of the DPPC main phase transition at 50 mol% sterol/steroid, which is inversely related to the miscibility of these compounds in fluid DPPC bilayers, also increases in the order β-OH > α-OH > CO, but this effect is attenuated in the saturated series with an inverted ring A/B orientation. Moreover, replacement of the double bond at C5–C6 with a saturated linkage and inversion of the ring A/B junction reduces both sterol/steroid solubility and the ability to order the hydrocarbon chains of fluid DPPC molecules all cases. Thus, the characteristic effects of sterols/steroids on fluid lipid bilayers are generally optimal when an OH group rather than CO group is present at C3, and when this OH group is in the equatorial (β) orientation, and when the orientation of the ring A/B fusion is trans rather than cis. Overall, these results demonstrate that variations in the saturation and stereochemistry of the steroid ring system influence the effect of variations in the nature and stereochemistry of the polar headgroup at C3 on the physical properties of phospholipid bilayers and vice versa. Moreover, the presence of a single double bond specifically at Δ5 is required to maximize sterol solubility in fluid DPPC bilayers.