In previous studies, we identified a 21 bp palindrome (-794 to -774) located within the negative regulatory element of the human CYP1A1 gene consisting of an 8 bp inverted repeat and 5 bp spacer. This element specifically binds protein(s) present in HepG2 nuclear extract preparations and is capable of down-regulating heterologous promoters and enhancers in transient expression assays. Conserved guanine/cytosine-rich regions which flank the palindrome also were implicated in this activity. In the present study, we examined similar regions from the rat (-881 to -746) and mouse (-822 to -683) CYP1A1 genes for their ability to bind nuclear protein and down-regulate heterologous promoters and enhancers. These rodent DNA fragments contain the conserved guanine/cytosine-rich sequences, as well as half-sites similar to those found in the human CYP1A1 palindrome. However, each half-site is separated by ∼40 bp. DNase I footprint analyses revealed the presence of rat and mouse nuclear proteins which gave a similar protection pattern as that observed with nuclear proteins from the human cell line, HepG2. Electrophoretic mobility shift assays with the human negative regulatory element demonstrated the formation of specific DNA-protein complexes with rat and mouse nuclear protein(s). Interestingly, two specific DNA-protein complexes were observed with rodent extracts as compared to the single specific complex seen with human extract. Specific binding was not observed with either the orthologous rat or mouse fragments using human or rodent extracts. In transient expression assays, the rat and mouse fragments were unable to down-regulate enhancer/promoter activity. This absence of negative regulatory activity occurred whether transfections were performed in human, rat or mouse hepatoma cell lines. The human negative regulatory element, which was previously shown to down-regulate heterologous enhancers/promoters ∼70% in human cells, did not exhibit this activity in rodent cell lines. UV cross-linking and southwestern blot analyses indicated a high degree of similarity between human and rodent NRE binding proteins, although some differences also were apparent. The possible implications of these findings with regards to species differences in the regulation of CYPIAI expression are discussed.