TBP (TATA box binding protein), a general transcription factor required for proper initiation of gene expression by RNA polymerase II, and minor groove binding drugs (MGBs) both interact with DNA within the minor groove at AT sites. This study has evaluated MGBs as inhibitors of DNA/TBP complex formation by gel mobility shift assays. Our results demonstrate that reversible MGBs (DAPI, distamycin A, Hoechst 33258, and netropsin) are effective inhibitors of the formation of DNA/TBP complex and that distamycin A is the most potent (0.16 microM inhibits TBP complex formation by 50%). CC-1065, a drug that covalently binds to DNA in the minor groove, is even more active than distamycin A (0.00085 microM inhibits TBP complex formation by 50%). Significantly more CC-1065 (0.009 microM) is required to break up preformed DNA/TBP complex compared to the drug concentration needed to prevent complex formation. In comparison, the order of drug addition has little influence on the ability of reversible MGBs to disrupt DNA/TBP complex. In the presence of TFIIA, a factor that enhances TBP association with DNA, greater drug concentrations (distamycin A and CC-1065, respectively) are needed to disrupt a preformed complex of DNA/TBP/TFIIA. In comparison to MGBs, drugs capable of binding to DNA by intercalation are generally weaker at blocking TBP complex formation except for hedamycin, which can intercalate and irreversibly bind to DNA and is as effective as reversible MGBs.