Low-density lipoprotein (LDL) delivers cholesterol to mammalian cells in the form of cholesteryl esters (CEs), but due to the lack of suitable tools, our understanding of the intracellular transport and hydrolysis of CEs is limited. We present a novel approach for studying LDL-derived CEs in cells using fatty acyl chain conjugates of the intrinsically fluorescent cholestatrienol (CTL). We demonstrate that CTL esters reconstituted into LDL particles are hydrolyzed in late endosomes and lysosomes (LE/LYSs) by acid lipase, while an LDL-derived CTL ether analogue cannot leave LE/LYSs. Using live-cell imaging, lipidomics, and multimodal Bayesian modeling, we discover a sequential biphasic transport of LDL-derived CTL to LE/LYSs with a half-time of 3.0 h. Hydrolyzed CTL derived from LDL-associated CTL esters is rapidly re-esterified with a similar half-time and stored in lipid droplets, demonstrating efficient sterol transport to the endoplasmic reticulum. Lack of functional Niemann-Pick C1 or C2 protein caused lysosomal accumulation of LDL-derived sterol. Using lipidomics and kinetic modeling, we also track LDL-derived CEs and triacylglycerols in cells and determine the uptake kinetics for each lipid species individually. Our novel approach allows for precise measurement of postendocytic trafficking and metabolism of LDL-derived cholesterol and other lipids in living cells.
Juhl et al. (Thu,) studied this question.