Rodent liver cytosol and other biological systems contain two proteins that bind polycyclic aromatic hydrocarbons (PAH) in a non covalent manner and that sediment at a different rate when centrifuged on sucrose gradient. The role of the smaller protein ("4S" PAH-BP) was studied. When DBA/2N mouse liver homogenate was incubated with 3H-BaP, most of the radioactivity was found in the microsomal subcellular fraction. The cytosol binding activity apparently decreased but reincubation of the cytosol with the radioactive ligand completely restored "4S" PAH-BP activity. The microsomal uptake of 3H-BaP can be studied in a reconstituted system in which microsomes are incubated with radioactive benzo(a)pyrene in the presence of crude cytosol. In these conditions the microsomal uptake rate of 3H-BaP increased with the temperature and at 37 degrees C ten minutes were required to reach the plateau. When cytosol was substituted by HEDG buffer, the amount of radioactivity found in the microsomes decreased drastically. 0.2 microM was the benzo(a)pyrene concentration required to saturate the microsomes. When microsomes were incubated with ammonium sulfate cytosolic fractions or with homogeneously purified "4S" PAH-BP, the 3H-BaP uptake was restored and reached the maximum with 3 micrograms/ml of purified protein. The radioactive benzo(a)pyrene bound to microsomes was oxidated in the presence of NADPH regenerating system. The oxidated products were discharged from microsomes only when "4S" PAH-BP was either present during the incubation or added at its end. Thus, this protein is able to transfer benzo(a)pyrene to the microsomal metabolization sites and to facilitate the release of oxidized products and, presumably, bind them.