The calbindin-D9K (CaBP9k) gene is mainly expressed in differentiated duodenal epithelial cells and is used as a model for studying the molecular mechanisms of intestine-specific transcription. The gene has been cloned, two major DNase-I-hypersensitive sites in the duodenum have been described, and a vitamin-D-response element has been identified. We have now analysed the transcription factors and regulatory sequences involved in the transcription of the CaBP9k gene in the intestine in ex vivo and in vitro experiments. Transfection experiments in intestinal (CaCo-2) and non-intestinal (HeLa) cell lines defined two regions in the 5'-flanking sequences of the rat CaBP9k gene. A minimal proximal region (-117 to +20) promoted transcription in both intestinal expressing and non-expressing cell lines. Tissue specificity was conferred by the sequences situated further upstream, which are responsible for complete repression in the non-intestinal cells. Intestinal transcription was specified by the proximal region, containing a specialized TATA box, and a distal region, which contains a previously described intestinal DNase-I-hypersensitive site. In vitro DNase I footprinting, electrophoretic mobility shift assays and antibody supershift assays were used to examine the factors bound to the proximal promoter region (-800 to +80 bp). Rat duodenal nuclear extracts protected 12 sites. Some of them appear to be binding sites for ubiquitous (nuclear factor 1) or hepatic-enriched sites (hepatocyte nuclear factors 1 and 4, enhancer binding protein alpha and beta factors. DNA binding studies and transfection experiments indicated that an intestine-specific transcription factor, caudal homeobox-2, binds to the TATA box of the rat CaBP9k gene. These data contribute to our understanding of the control of the intestinal transcription of the CaBP9k gene and demonstrate that several trans-acting factors, other than the vitamin D receptor, may be factors for intestine-specific CaBP9k gene expression.