Filipin (a polyene antibiotic) interacts specifically with cholesterol in membranes, producing characteristic 25 nm-diameter deformation (pitlike lesions) within the membrane plane detectable by freeze-fracture electron microscopy. Utilizing this probe, the distribution of cholesterol molecules in membranes and in lamellar structures between horny cells was investigated in human skin. The plasma membranes of basal, spinous, and granular cells reacted extensively with filipin except for desmosomal membrane portions. However, the plasma membranes of horny cells were rarely labeled with filipin, while lamellar structures between horny cells were well labeled. These observations indicate the distinct difference in susceptibility to filipin among the plasma membranes of viable cells and horny cells, and the lipid lamellar structures. Whenever horny cell plasma membranes were affected with filipin, they revealed a low deformability showing shallow pits or low protrusions. This low deformability may be due to greater membrane rigidity rather than a lower content of cholesterol, although the possibility of a low amount of cholesterol cannot be excluded. Lamellar bodies in granular cells were well labeled in the limiting membranes but poorly labeled in the internal lamellar structures. The regions of gap junctions were absolutely unlabeled. Filipin-cholesterol complexes were produced very close to the junctional strands but did not appear to disrupt the junctional structure of tight junctions. Nuclear membranes were affected only in the outer membrane with filipin. These results suggest that keratinocytes undergo a distinctive reduction in membrane deformability or in free-cholesterol content at the transition from living to dead cells, and display a heterogeneity in cholesterol distribution in human epidermal cell membranes.