Zinc-finger domains of the transcriptional repressor KLF15 bind multiple sites in rhodopsin and IRBP promoters including the CRS-1 and G-rich repressor elements

Zinc finger proteins are among the most abundant proteins in eukaryotic genomes. Their functions are extraordinarily diverse and include DNA recognition, RNA packaging, transcriptional activation, regulation of apoptosis, protein folding and assembly, and lipid binding. Zinc finger structures are as diverse as their functions. Structures have recently been reported for many new zinc finger domains with novel topologies, providing important insights into structure/function relationships. In addition, new structural studies of proteins containing the classical Cys(2)His(2) zinc finger motif have led to novel insights into mechanisms of DNA binding and to a better understanding of their broader functions in transcriptional regulation.

The otd/Otx gene family encodes paired-like homeodomain proteins that are involved in the regulation of anterior head structure and sensory organ development. Using the yeast one-hybrid screen with a bait containing the Ret 4 site from the bovine rhodopsin promoter, we have cloned a new member of the family, Crx (Cone rod homeobox). Crx encodes a 299 amino acid residue protein with a paired-like homeodomain near its N terminus. In the adult, it is expressed predominantly in photoreceptors and pinealocytes. In the developing mouse retina, it is expressed by embryonic day 12.5 (E12.5). Recombinant Crx binds in vitro not only to the Ret 4 site but also to the Ret 1 and BAT-1 sites. In transient transfection studies, Crx transactivates rhodopsin promoter-reporter constructs. Its activity is synergistic with that of Nrl. Crx also binds to and transactivates the genes for several other photoreceptor cell-specific proteins (interphotoreceptor retinoid-binding protein, beta-phosphodiesterase, and arrestin). Human Crx maps to chromosome 19q13.3, the site of a cone rod dystrophy (CORDII). These studies implicate Crx as a potentially important regulator of photoreceptor cell development and gene expression and also identify it as a candidate gene for CORDII and other retinal diseases.

Comparisons between human and rodent DNA sequences are widely used for the identification of regulatory regions (phylogenetic footprinting), and the importance of such intergenomic comparisons for promoter annotation is expanding. The efficacy of such comparisons for the identification of functional regulatory elements hinges on the evolutionary dynamics of promoter sequences. Although it is widely appreciated that conservation of sequence motifs may provide a suggestion of function, it is not known as to what proportion of the functional binding sites in humans is conserved in distant species. In this report, we present an analysis of the evolutionary dynamics of transcription factor binding sites whose function had been experimentally verified in promoters of 51 human genes and compare their sequence to homologous sequences in other primate species and rodents. Our results show that there is extensive divergence within the nucleotide sequence of transcription factor binding sites. Using direct experimental data from functional studies in both human and rodents for 20 of the regulatory regions, we estimate that 32%-40% of the human functional sites are not functional in rodents. This is evidence that there is widespread turnover of transcription factor binding sites. These results have important implications for the efficacy of phylogenetic footprinting and the interpretation of the pattern of evolution in regulatory sequences.