Synthesis and characterization of novel intrinsically fluorescent analogs of cholesterol with improved photophysical properties

Abstract

AbstractLive-cell imaging of cholesterol trafficking depends on suitable cholesterol analogs. However, existing fluorescent analogs of cholesterol either show very different physico-chemical properties compared to cholesterol or demand excitation in the ultraviolet spectral region. We present novel intrinsically fluorescent sterols containing four conjugated double bonds in the ring system and either a hydroxy or a keto group in the C3 position. Synthesis of these probes involves dehydrogenation of 7-dehydrocholesterol using mercury(II) acetate, Swern oxidation/dehydrogenation, and stereoselective Luche reduction. Molecular dynamics simulations and nuclear magnetic resonance spectroscopy reveal that the analog with a 3’-hydroxy-group like cholesterol can condense fatty acyl chains and form hydrogen bonds to water molecules at the bilayer interface. The emission of both probes is red-shifted by 80-120 nm compared to the widely used sterol analogs dehydroergosterol or cholestatrienol. This allows for their imaging on conventional microscopes, as we here show in giant unilamellar vesicles. These experiments reveal a preferred partitioning of both sterol probes into the biologically relevant liquid-ordered phase. In conclusion, we present a synthesis strategy leading to novel intrinsically fluorescent sterol probes with close resemblance of cholesterol. Their improved photophysical properties will allow for live-cell imaging of sterol transport in the future.