Members of the steroid/hormone nuclear receptor superfamily regulate target gene transcription via recognition and association with specific cis-acting sequences of DNA, called hormone response elements (HREs). The identification of novel HREs is fundamental to understanding the physiological function of nuclear receptor-mediated signalling pathways. A number of these receptors are transcriptionally active, or can be induced to an active state, when expressed in the yeast strain Saccharomyces cerevisiae. This aspect of nuclear receptor activity was used to screen random rat genomic DNA fragments for their ability to function as a HRE for the farnesoid X-activated receptor (FXR). An isolated genomic fragment mediated FXR transcriptional activation without the co-expression of the retinoid-X receptor (RXR), a receptor previously thought to be an obligate heterodimer partner for FXR function. This genomic sequence of DNA contained a pair of highly conserved HRE half-sites arranged in an everted orientation and separated by 3 bp (ER3). Furthermore, it was located 240 bp from a highly conserved TATA box motif. A minimal ER3 sequence of DNA was further demonstrated to function as a FXR HRE and was bound in vitro by FXR-expressing yeast extracts. Using RT-PCR, an expressed mRNA fragment was identified within an 8 kb region downstream of the putative TATA box motif. This sequence of DNA was observed to bear homology to a cDNA found in mouse blastocyst. These findings define a novel FXR DNA binding specificity but, more importantly, these data suggest that this strategy might be universally applied to any transcription system that can be reconstituted in yeast.
Copyright 2001 John Wiley & Sons, Ltd.