In rodents, cholesterol for adrenal steroidogenesis is derived mainly from high‐density lipoproteins (HDL) via the HDL receptor, scavenger receptor‐BI (SR‐BI). In humans cholesterol for steroidogenesis is considered to be derived from the low‐density lipoprotein (LDL) receptor pathway, and the contribution of SR‐BI to that is unknown. In the present study SR‐BI expression and regulation by steroidogenic stimuli was analysed in human adrenocortical cells and compared with LDL receptor expression. In addition, the functional contribution of both receptors for cholesteryl ester delivery to human adrenocortical cells was compared. Northern blot and reverse transcription–PCR amplification and sequence analysis demonstrated the presence of SR‐BI mRNA in foetal and adult human adrenal cortex. Furthermore, SR‐BI mRNA was expressed to similar levels in human primary adrenocortical and adrenocortical carcinoma NCI‐H295 cells, indicating its presence in the steroid‐producing cells. Treatment of NCI‐H295 cells with 8Br‐cAMP, a stimulator of glucocorticoid synthesis via the protein kinase A second messenger signal transduction pathway, resulted in an increase of both SR‐BI and LDL receptor mRNA levels in a time‐ and dose‐dependent manner. The induction of SR‐BI and LDL receptor by cAMP was independent of ongoing protein synthesis and occurred at the transcriptional level. Ligand blot experiments indicated that a protein of similar size to SR‐BI is the major HDL‐binding protein in NCI‐H295 cells. Western blot analysis demonstrated that cAMP treatment increased the levels of LDL receptor and, to a lesser extent, SR‐BI protein in NCI‐H295 cells. Binding and uptake of cholesterol was quantitatively smaller from HDL than from LDL, both in basal as well as in cAMP‐stimulated cells. Scatchard analysis under basal conditions indicated that NCI‐H295 cells express twice as many specific binding sites for LDL than for HDL. Dissociation constant values (K_d; in nm) were approximately five times higher for HDL than for LDL, indicating a lower affinity of HDL compared with LDL. The combined effects of these two parameters and the low cholesteryl ester content of HDL subfraction 3 (HDL₃) contributes to a lower cholesteryl ester uptake from HDL than from LDL by the NCI‐H295 cells. In conclusion, both the SR‐BI and LDL receptor genes are expressed in the human adrenal cortex and coordinately regulated by activators of glucocorticoid synthesis. In contrast to rodents, in human adrenocortical cells the HDL pathway of cholesterol delivery appears to be of lesser importance than the LDL pathway. Nevertheless, the SR‐BI pathway may become of major importance in conditions of functional defects in the LDL receptor pathway.