Cytosolic sulfotransferases catalyze sulfonation of small molecules such as drug, steroid hormones, bile acids, and neurotransmitters. Two main classes of sulfotransfease were identified according to their selectivity on substrates, which is corresponding to two major gene families among cytosolic sulfotransferases: the phenol SULT family (designated SULT1) and the hydroxysteroid SULT family (designated SULT2). SULT1 catalyzes the sulfonation of small phenolic molecules like p-Nitrophenol. SULT2 catalyzes the sulfonation of alcoholic compounds like dehydroepiandrosterone. These enzymes can adopt broad range of substrates, but how these two classes of sulfotransferases select their own substrates is unclear. Structural and sequential comparisons indicated important variations in enzyme active sites between SULT1 and SULT2. We proposed that an active site amino acid, F81, of SULT1A1 plays important role in distinguishing the phenolic and alcoholic compounds. A series of mutation on this amino acid (F81) showed that F81Y, F81M still maintained SULT activity with phenolic substrates; F81A, F81G, F81L, F81W drastically decreased the SULT activity with phenolic substrates and significantly increased its activity toward alcoholic compounds. The corresponding amino acid for F81 in SULT2A1 was W77. However, W77F, W77Y mutants exhibited little changed activity with alcoholic substrates indicating that SULT2A1 may have different mechanism for selecting substrates. We proposed that the whole substrate binding site of SULT2 was used to select substrate for multi-ring structure. The kcat of SULT2A1 using estrone as substrate was in the same order with SULT1A1. This exhibited the SULT2A1 could catalyze estrone, and it could use either phenolic compounds or hydroxysteroids as substrate. A substrate-selecting mechanism of sulfotransferase was proposed according to our results. SULT1A1 used the side chain of F81 as a spatial barrier for excluding alcoholic substrates that have tetrahedral structures. SULT2 preferred the multi-ring structures as substrates which can be either phenolic or alcoholic compounds. This mechanism is consistent with a dissociative mechanism for the transfer of sulfuryl group from PAPS to alcoholic or phenolic substrates. This mechanism explained how SULT1 and SULT2 may use similar mechanism for sulfuryl group transfer even though the pKa values of hydroxyl group on phenolic (~10) and on alcoholic compound (~15) differ in five orders of magnitude.