Erx, a novel retina-specific homeodomain transcription factor, can interact with Ret 1/PCEI sites

A 350 bp region of the proximal promoter of Rds drives cell-type specific gene expression

RDS (retinal degeneration slow) is a photoreceptor-specific tetraspanin protein required for the biogenesis and maintenance of rod and cone outer segments. Mutations in the Rds gene are associated with multiple forms of rod- and cone-dominant retinal degeneration. To gain more insight into the mechanisms underlying the regulation of this gene, the identification of regulatory sequences within the promoter of Rds was undertaken. A 3.5 kb fragment of the 5' flanking region of the mouse Rds gene was isolated and binding sites for Crx, Otx2, Nr2e3, RXR family members, Mef2C, Esrrb, NF1, AP1, and SP1 in addition to several E-boxes, GC-boxes and GAGA-boxes were identified. Crx binding sequences were conserved in all mammalian species examined. Truncation expression analysis of the Rds promoter region in Y-79 retinoblastoma cells showed maximal activity in the 350 bp proximal promoter region. We also show that inclusion of more distal fragments reduced promoter activity to the basal level, and that the promoter activities are cell-type and direction specific. Co-transfection with Nrl increased promoter activity, suggesting that this gene positively regulates Rds expression. Based on these findings, a relatively small fragment of the Rds promoter may be useful in future gene transfer studies to drive gene expression in photoreceptors.

Regulation of photoreceptor gene expression by the retinal homeobox (Rx) gene product

The retinal homeobox (Rx) gene product is essential for eye development. However little is known about its molecular function. It has been demonstrated that Rx binds to photoreceptor conserved element (PCE-1), a highly conserved element found in the promoter region of photoreceptor-specific genes such as rhodopsin and red cone opsin. We verify that Rx is co-expressed with rhodopsin and red cone opsin in maturing photoreceptors and demonstrate that Rx binds to the rhodopsin and red cone opsin promoters in vivo. We also find that Rx can cooperate with the Xenopus analogs of Crx and Nrl, otx5b and XLMaf (respectively), to activate a Xenopus opsin promoter-dependent reporter. Finally, we demonstrate that reduction of Rx expression in tadpoles results in decreases in expression of several PCE-1 containing photoreceptor genes, abnormal photoreceptor morphology, and impaired vision. Our data suggests that Rx, in combination with other transcription factors, is necessary for normal photoreceptor gene expression, maintenance, and function. This establishes a direct role for Rx in regulation of genes expressed in a differentiated cell type.

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

BACKGROUND

In the retina, many of the genes that encode components of the visual transduction cascade and retinoid recycling are exclusively expressed in photoreceptor cells and show highly stereotyped temporal and spatial expression patterns. Multiple transcriptional activators of photoreceptor-specific genes have been identified, but little is known about negative regulation of gene expression in the retina. We recently identified KLF15, a member of the Sp/Krüppel-like Factor family of zinc-finger containing transcription factors, as an in vitro repressor of the promoters of the photoreceptor-specific genes rhodopsin and IRBP/Rbp3. To gain further insight into the mechanism of KLF15-mediated regulation of gene expression, we have characterized the binding characteristics and specificity of KLF15's DNA binding domains and defined the KLF15 binding sites in the rhodopsin and IRBP promoters.

RESULTS

In EMSA and DNAseI footprinting assays, a KLF15-GST fusion protein containing the C-terminal zinc-finger domains (123 amino acids) showed zinc-dependent and sequence-specific binding to a 9 bp consensus sequence containing a core CG/TCCCC. Both the bovine rhodopsin and IRBP promoters contained multiple KLF15 binding sites that included the previously identified CRS-1 and G-rich repressor elements. KLF15 binding sites were highly conserved between the bovine, human, chimp and dog rhodopsin promoters, but less conserved in rodents. KLF15 reduced luciferase expression by bRho130-luc (containing 4 KLF15 sites) and repressed promoter activation by CRX (cone rod homeobox) and/or NRL (neural retina leucine zipper), although the magnitude of the reduction was smaller than previously reported for a longer bRho225-luc (containing 6 KFL15 sites).

CONCLUSION

KLF15 binds to multiple 9 bp consensus sites in the Rhodospin and IRBP promoters including the CRS-1 and G-rich repressor elements. Based on the known expression pattern of KLF15 in non-photoreceptor cells, we hypothesize an in vivo role for KLF15 in repressing photoreceptor-specific gene expression in the inner retina.

Truncation and mutagenesis analysis of the human X-arrestin gene promoter

X-arrestin (arrestin-3) is an arrestin present specifically in the outer segments of red-, green-, and blue-cone photoreceptors. The X-arrestin gene is on Xcen-q22, and consists of 17 exons with a promoter containing a TATA box and elements important for photoreceptor expression, including three CRX and one PCE-1-like element. In order to delineate the promoter structure necessary for the pan-cone-specific expression of X-arrestin, the expression of the gene in retinoblastoma cell lines was investigated, and a structure-function analysis of the promoter was conducted in the appropriate cellular substrate. Expression of X-arrestin was detected at a low level in the Y79 retinoblastoma cell line but not in the WERI retinoblastoma cell line. Truncation and expression analysis of the X-arrestin promoter in Y79 showed maximal activity in the proximal 378-bp region containing the CRX and PCE-1-like elements upstream of the TATA and CAAT boxes and a negative regulator in the distal 1-2-kbp region. Mutagenesis of the three CRX and PCE-1-like elements and expression analysis demonstrated complete elimination of the promoter activity. Mutagenesis of the TATA box and PCE-1-like element individually resulted in similar decrease in promoter activity, but the decrease in the promoter activity was greater when the CRX elements were mutagenized with a 5' to 3' spatial gradient in the negative effect, suggesting a cooperative effect of the three CRX elements. The regulation of expression from this promoter may involve the binding of a multi-protein enhanceosome complex at the CRX triplet and the PCE-1-like element, resulting in the recruitment and activation of the RNA polymerase II complex at the downstream TATA box.

Conserved transcriptional activators of the Xenopus rhodopsin gene

Vertebrate rhodopsin promoters exhibit striking sequence identities proximal to the initiation site, suggesting that conserved transcription factors regulate rhodopsin expression in these animals. We identify and characterize two transcriptional activators of the Xenopus rhodopsin gene: homologs of the mammalian Crx and Nrl transcription factors, XOtx5 and XL-Nrl (originally named XL-maf), respectively. XOtx5 stimulated transcription approximately 10-fold in human 293 cells co-transfected with a plasmid containing the rhodopsin promoter (-508 to +41) upstream of luciferase, similar to the approximately 6-fold stimulation with human Crx. XL-Nrl stimulated transcription approximately 27-fold in mammalian 293 cells co-transfected with the rhodopsin luciferase reporter, slightly more than the approximately 17-fold stimulation with Nrl. Together, the Xenopus transcription factors synergistically activated the rhodopsin promoter (approximately 140-fold), as well as in combination with mammalian homologs. Deletion of the Nrl-response element, TGCTGA, eliminated the synergistic activation by both mammalian and Xenopus transcription factors. Deletion of the conserved ATTA sequences (Ret-1 or BAT-1), binding sites for Crx, did not significantly decrease activation by Crx/XOtx5. However, there was increased activation by Nrl/XL-Nrl and an increased synergy when the Ret-1 site was disrupted. These results illustrate conservation of mechanisms of retinal gene expression among vertebrates. In transgenic tadpoles, XOtx5 and XL-Nrl directed premature and ectopic expression from the Xenopus rhodopsin promoter-GFP transgene. Furthermore, activation of the endogenous rhodopsin gene was also observed in some animals, showing that XOtx5 and XL-Nrl can activate the promoter in native chromatin environment.

Retina-specific gene expression and improved DNA transfection in WERI-Rb1 retinoblastoma cells

We have studied retina-specific gene expression and gene promoter activity in WERI-Rb1 retinoblastoma cells. In general, the expression of endogenous genes matched the efficiency of promoter activity of the transfected gene: interphotoreceptor retinoid binding protein and phosphodiesterase-beta mRNAs and reporter activities were readily detected while other retina-specific messages were at or below the detection limit in WERI-Rb1 cells. Phosphodiesterase-beta promoter appeared active in all six cell lines tested. The viral SV40 promoter is very weak in WERI-Rb1 cells, which has implications for its use in gene constructs targeted to the photoreceptors. Our results also show that polyethyleneimine 25 is an efficient and simple carrier for DNA. The optimized transfection conditions permit the use of 24-well plates and low amounts of DNA for improved analysis of promoter activities, as compared to previous studies. Our results are expected to facilitate further research on retina-specific gene expression.

CRALBP transcriptional regulation in ciliary epithelial, retinal Müller and retinal pigment epithelial cells

Cellular retinaldehyde binding protein (CRALBP) functions in the visual cycle and mutations in the RLBP1 gene can lead to blindness. RLBP1 promoter analyses have been pursued in vitro as an approach to deciphering the mechanism controlling cell-specific expression of CRALBP. Reporter activity of wildtype and mutant RLBP1 promoter constructs suggest that CRALBP transcriptional regulation may be similar in the ciliary epithelium (CE) and retinal pigment epithelium (RPE) but different in Müller cells. Results in RPE cells refine the location of an RLBP1 enhancer element to within -1826 to -1749 bp and a repressor element to within -702 to -635 bp.

Pineal expression-promoting element (PIPE), a cis-acting element, directs pineal-specific gene expression in zebrafish

The pineal gland, sharing morphological and biochemical similarities with the retina, plays a unique and central role in the photoneuroendocrine system. The unique development of the pineal gland is directed by a specific combination of the expressed genes, but little is known about the regulatory mechanism underlying the pineal-specific gene expression. We isolated a 1.1-kbp fragment upstream of the zebrafish exo-rhodopsin (exorh) gene, which is expressed specifically in the pineal gland. Transgenic analysis using an enhanced green fluorescent protein reporter gene demonstrated that the proximal 147-bp region of the exorh promoter is sufficient to direct pineal-specific expression. This region contains three copies of a putative cone rod homeobox (Crx)Otx-binding site, which is known to be required for expression of both retina- and pineal-specific genes. Deletion and mutational analyses of the exorh promoter revealed that a previously uncharacterized sequence TGACCCCAATCT termed pineal expression-promoting element (PIPE) is required for pineal-specific promoter activity in addition to the CrxOtx-binding sites. By using the zebrafish rhodopsin (rh) promoter that drives retina-specific expression, we created a reporter construct having ectopic PIPE in the rh promoter at a position equivalent to that in the exorh promoter by introducing five nucleotide changes. Such a slight modification in the rh promoter induced ectopic enhanced green fluorescent protein expression in the pineal gland without affecting its retinal expression. These results identify PIPE as a critical cis-element contributing to the pineal-specific gene expression, in combination with the CrxOtx-binding site(s).

Molecular aspects of vertebrate retinal development

The formation of retina from neural plate has been mapped extensively by anatomical and molecular methods. The major cascades of transcription factor expression have been identified, and deficits resulting from transcription factor knockouts are well characterized. There is extensive cross-regulation, both positive and negative, at the transcriptional level between transcription factors and this is vital in the formation of neural compartments. Many transcription factors are important at both early stages of optic cup formation and later stages of terminal differentiation of retinal cell types. The transcription factor cascades can be regulated by extrinsic factors, and some of the intracellular signaling pathways whereby this is achieved have been identified. Defining the quantitative interactions between regulatory molecules will be the next step in understanding this excellent model of vertebrate central nervous system (CNS) development.

Transcriptional regulation of the chicken hydroxyindole-O-methyltransferase gene by the cone-rod homeobox-containing protein

Functional differentiation of photoreceptor cells involves the expression of two sets of genes: those encoding the proteins of the phototransduction cascade and those encoding the enzymes of melatonin synthesis. The transcription factor Crx (cone-rod homeobox) plays a major role in the differentiation and maintenance of the photoreceptor phenotype. Previous studies have shown that this effect of Crx is correlated with its ability to transactivate several genes of the phototransduction cascade. Here, we show that Crx can also act on the gene encoding the melatonin-synthesizing enzyme, hydroxyindole-O-methyltransferase (HIOMT, EC 2.1.1.4). Three of the six putative Crx-binding sites found in the chicken HIOMT promoter interact directly with recombinant Crx and bound a pineal/retina-specific protein showing DNA-binding characteristics similar to those of Crx. In transient transfection experiments, Crx transactivated transcription of a reporter gene from the chicken HIOMT promoter. Transactivation was observed even with a portion of promoter carrying only one Crx-binding site and it was abolished by a mutation in this cis-regulatory element. These data indicate that Crx may participate in photoreceptor cell differentiation, not only by acting on the genes of the phototransduction cascade, but also by controlling the expression of the genes involved in melatonin synthesis.

Xenopus rhodopsin promoter. Identification of immediate upstream sequences necessary for high level, rod-specific transcription

To understand the mechanisms that control the cell-specific visual pigment gene transcription, the Xenopus rhodopsin 5' regulatory region has been characterized in vivo using transient transfection of Xenopus embryos and transgenesis. The principal control sequences were located within -233/+41, a region with significant conservation with mammalian rhodopsin genes. DNase footprinting indicated seven distinct regions that contain potential cis-acting elements. Sequences near the initiation site (-45/+41, basal region) were essential, but not sufficient, for rod-specific transcription. Two negative regulatory regions were found, one between -233 to -202, with no apparent similarity to known elements, and a second Ret-1-like CAAT (-136/-122) motif. Deletion of either sequence led to a 2-3-fold increase in expression levels, without a change in rod specificity. Sequences between -170 to -146, which contain an E-box motif, were necessary for high level expression in transgenic tadpoles but not in transient transfections. Sequences between -84 and -58, which contained an NRE-like consensus were found to be necessary for high level expression in both assays. Although expression levels were modulated by various proximal sequences in the rhodopsin promoter, none of the tested sequences were found to be necessary for rod specificity. Promoter constructs with a consensus BAT-1 sequence in conjunction with an NRE-like element upstream of the basal promoter directed low level green fluorescent protein expression in the central nervous system in transgenic tadpoles. These results suggest that rod cell-specific expression of rhodopsin is controlled by redundant elements in the proximal promoter.

The photoreceptor cell-specific nuclear receptor is an autoantigen of paraneoplastic retinopathy

OBJECTIVES

To report a novel antibody associated with paraneoplastic retinopathy and to characterize the retinal autoantigen.

METHODS

Immunohistochemistry of rat and human tissues was used to identify antiretinal antibodies. Serologic screening of a bovine retinal cDNA expression library was performed to clone the target antigen.

RESULTS

A 72-year-old woman presented with a 6-month history of progressive visual loss, bilateral central scotomas, light flashes, and night blindness. Visual acuity was 20/40 OD and 20/30 OS. There was generalized loss of retinal pigment and narrow arterioles; discs were normal in appearance. The electroretinogram showed no response. Chest computed tomograph scan demonstrated a right lung mass; biopsy revealed poorly differentiated carcinoma. The patients' serum contained antibodies that immunolabeled nuclei of cells of the outer--and to a lesser extent, the inner--nuclear layer of the adult rat retina. No reactivity was identified with nonretinal adult human or rat tissues. Reactivity was seen in the developing rat embryo. Serologic screening of a bovine retinal library resulted in the isolation of three overlapping clones, encoding a protein highly homologous to the human photoreceptor cell-specific nuclear receptor gene product.

CONCLUSIONS

The target antigen of an antibody associated with paraneoplastic retinopathy is the photoreceptor cellspecific nuclear receptor, a member of a conserved family of nuclear receptors involved in photoreceptor cell development or maintenance.

A novel promoter element, photoreceptor conserved element II, directs photoreceptor-specific expression of nocturnin in Xenopus laevis

Nocturnin is a vertebrate circadian clock-regulated gene, and in Xenopus laevis its mRNA is specifically expressed in retinal photoreceptor cells. We have investigated the transcriptional regulatory mechanism that drives this precise spatial expression pattern of the nocturnin gene. A deletion series of the nocturnin 5'-flanking sequence driving the green fluorescence protein (GFP) reporter was used to generate transgenic Xenopus tadpoles. We found that a construct containing 2.6 kilobase pairs of 5'-flanking sequence targeted high level GFP reporter expression specifically to photoreceptor cells, in a pattern identical to endogenous nocturnin. This photoreceptor-specific expression pattern was maintained with several further deletions of 5'-upstream sequence, including a short 59-base pair fragment. Within this region of 59 base pairs, three perfect repeats of a novel protein binding site were identified by electrophoretic mobility shift assay. Competitions using varying oligonucleotide sequences demonstrated that the sequence required for protein binding is CAGACAGGCTATA, designated photoreceptor-conserved element II (PCE II). The protein complex that binds to this element is enriched in retinal extracts, and mutations of PCE II which fail to bind the protein complex also fail to direct GFP reporter expression to photoreceptors. These results indicate that the PCE II in the proximal promoter of the nocturnin gene is sufficient for driving the photoreceptor-specific expression of nocturnin.

The zinc finger transcription factor, MOK2, negatively modulates expression of the interphotoreceptor retinoid-binding protein gene, IRBP

The human and murine MOK2 orthologue genes encode Krüppel/TFIIIA-related zinc finger proteins, which are factors able to recognize both DNA and RNA through their zinc finger motifs. MOK2 proteins have been shown to bind to the same 18-base pair (bp)-specific sequence in duplex DNA. This MOK2-binding site was found within introns 7 and 2 of human PAX3 and interphotoreceptor retinoid-binding protein (IRBP) genes, respectively. As these two genes are expressed in the brain as MOK2, we have suggested that PAX3 and IRBP genes are two potentially important target genes for the MOK2 protein. In this study, we focused our attention on IRBP as a potential MOK2 target gene. Sequence comparison and binding studies of the 18-bp MOK2-binding sites present in intron 2 of human, bovine, and mouse IRBP genes show that the 3'-half sequence is the essential core element for MOK2 binding. Very interestingly, 8-bp of this core sequence are found in a reverse orientation, in the IRBP promoter. We demonstrate that MOK2 can bind to the 8-bp sequence present in the IRBP promoter and repress its transcription when transiently overexpressed in retinoblastoma Weri-RB1 cells. In the IRBP promoter, it appears that the TAAAGGCT MOK2-binding site overlaps with the photoreceptor-specific CRX-binding element. We suggest that MOK2 represses transcription by competing with the cone-rod homeobox protein (CRX) for DNA binding, thereby decreasing transcriptional activation by CRX. Furthermore, we show that Mok2 expression in the developing mouse and in the adult retina seems to be concordant with IRBP expression.

Reproducible high efficiency gene transfer into Y79 retinoblastoma cells using adenofection

Several photoreceptor-specific genes are actively transcribed in Y79 retinoblastoma (Rb) cells, making this cell line potentially useful for the study of photoreceptor metabolism. The utility of these cells is limited because commonly used methods of gene transfer into Y79 cells are inefficient and lack reproducibility. In contrast, we found that adenovirus transduction yields high efficiency gene transfer, however, generation of recombinant adenovirus is lengthy and time consuming. Here, we show that adenofection, a method of coupling adenovirus to plasmid DNA for improved gene transfer, is efficient for gene delivery into Y79 cells. Recombinant adenovirus expressing bacterial lacZ was noncovalently complexed to GFP or luciferase reporter plasmids with polyethylenimine. Efficiency of plasmid gene delivery was determined by monitoring GFP fluorescence. For comparison, calcium phosphate-mediated or cationic lipid transfection was performed in Y79 and HEK293 cells using standard protocols. The adenofection protocol yielded significantly higher efficiencies in Y79 cells than that obtained in these cells with calcium phosphate or cationic lipids. This method will facilitate any experiment requiring reproducible high-level gene transfer. Here, we show that adenofection can be used to analyze activity of the rod photoreceptor PDE6A gene promoter.

The leucine zipper of NRL interacts with the CRX homeodomain. A possible mechanism of transcriptional synergy in rhodopsin regulation

Photoreceptor-specific expression of rhodopsin is mediated by multiple cis-acting elements in the proximal promoter region. NRL (neural retina leucine zipper) and CRX (cone rod homeobox) proteins bind to the adjacent NRE and Ret-4 sites, respectively, within this region. Although NRL and CRX are each individually able to induce rhodopsin promoter activity, when expressed together they exhibit transcriptional synergy in rhodopsin promoter activation. Using the yeast two-hybrid method and glutathione S-transferase pull-down assays, we demonstrate that the leucine zipper of NRL can physically interact with CRX. Deletion analysis revealed that the CRX homeodomain (CRX-HD) plays an important role in the interaction with the NRL leucine zipper. Although binding with the CRX-HD alone was weak, a strong interaction was detected when flanking regions including the glutamine-rich and the basic regions that follow the HD were included. A reciprocal deletion analysis showed that the leucine zipper of NRL is required for interaction with CRX-HD. Two disease-causing mutations in CRX-HD (R41W and R90W) that exhibit reduced DNA binding and transcriptional synergy also decrease its interaction with NRL. These studies suggest novel possibilities for protein-protein interaction between two conserved DNA-binding motifs and imply that cross-talk among distinct regulatory pathways contributes to the establishment and maintenance of photoreceptor function.

Modulation of CRX transactivation activity by phosducin isoforms

Phosducin (Phd) and Phd-like proteins (PhLPs) selectively bind guanine nucleotide protein (G protein) betagamma subunits (Gbetagamma), while Phd-like orphan proteins (PhLOPs) lack the major functional domain for the binding of Gbetagamma. A retina- and pineal gland-specific transcription factor, cone-rod homeobox (CRX), was identified by a yeast two-hybrid screen using PhLOP1 as the bait. Direct protein-protein interactions between Phd or PhLOP1 and CRX were demonstrated using a beta-galactosidase quantitative assay in the yeast two-hybrid system and were confirmed by an in vitro binding assay and a glutathione S-transferase (GST) pull-down assay. To determine if the interaction with Phd or PhLOP1 affected CRX transactivation, a 120-bp interphotoreceptor retinoid binding protein (IRBP) promoter-luciferase reporter construct containing a CRX consensus element (GATTAA) was cotransfected into either COS-7 or retinoblastoma Weri-Rb-1 cells with expression constructs for CRX and either Phd or PhLOP1. Phd and PhLOP1 inhibited the transcriptional activation activity of CRX by 50% during transient cotransfection in COS-7 cells and by 70% in Weri-Rb-1 cells and COS-7 cells stably transfected with CRX. Phd inhibited CRX transactivation in a dose-dependent manner. Whereas Phd is a cytoplasmic phosphoprotein, coexpression of Phd with CRX results in Phd being localized both in the cytoplasm and nucleus. By contrast, PhLOP1 is found in the nucleus even without CRX coexpression. To address the physiological relevance of these potential protein interacting partners, we identified immunoreactive proteins for Phd and CRX in retinal cytosolic and nuclear fractions. Immunohistochemical analysis of bovine retinas reveals colocalization of Phd isoforms with CRX predominantly in the inner segment of cone cells, with additional costaining in the outer nuclear layer and the synaptic region. Our findings demonstrate that both Phd and PhLOP1 interact directly with CRX and that each diminishes the transactivation activity of CRX on the IRBP promoter. A domain that interacts with CRX is found in the carboxyl terminus of the Phd isoforms. Phd antibody-immunoreactive peptides are seen in light-adapted mouse retinal cytosolic and nuclear extracts. Neither Phd nor PhLOP1 affected CRX binding to its consensus DNA element in electrophoretic mobility shift assays. A model that illustrates separate functional roles for interactions between Phd and either SUG1 or CRX is proposed. The model suggests further a mechanism by which Phd isoforms could inhibit CRX transcriptional activation.

Genomic organization of the human rod photoreceptor cGMP-gated cation channel beta-subunit gene

We previously reported that the CNGB1 locus encoding the rod photoreceptor cGMP-gated channel beta-subunit is complex, comprising non-overlapping transcription units that give rise to at least six transcripts (Ardell, M.D., Aragon, I., Oliveira, L., Porche, G.E., Burke, E., Pittler, S.J., 1996. The beta subunit of human rod photoreceptor cGMP-gated cation channel is generated from a complex transcription unit. FEBS Lett. 389, 213-218). To further understand the transcriptional regulation of this extraordinarily complex locus, and to develop a screen for defects in the gene in patients with hereditary disease, we determined its genomic organization and DNA sequence. The CNGB1 locus consists of 33 exons, which span approximately 100kb of genomic DNA on chromosome 16. The beta-subunit comprises two domains, an N-terminal glutamic acid-rich segment (GARP), and a C-terminal channel-like portion. Two additional exons encoding a short GARP transcript and a truncated channel-like transcript have been identified. A major transcription start point was identified 79bp upstream of the initiator ATG. To begin analysis of the basis for the generation of multiple transcripts, and to identify promoters driving expression in retina, approximately 2.5kb of the upstream region were sequenced. Putative cis-elements, which can bind the retina-specific transcription factors Crx and Erx, were found immediately upstream of the transcription start point, and may be important for gene expression in this tissue. From our analysis, a model is reported to account for at least four of the retinal transcripts.

Both PCE-1/RX and OTX/CRX interactions are necessary for photoreceptor-specific gene expression

RX, a homeodomain-containing protein essential for proper eye development (Mathers, P. H. Grinberg, A., Mahon, K. A., and Jamrich, M. (1997) Nature 387, 603-607), binds to the photoreceptor conserved element-1 (PCE-1/Ret 1) in the photoreceptor cell-specific arrestin promoter and stimulates gene expression. RX is found in many retinal cell types including photoreceptor cells. Another homeodomain-containing protein, CRX, which binds to the OTX element to stimulate promoter activity, is found exclusively in photoreceptor cells (Chen, S., Wang, Q. L., Nie, Z., Sun, H., Lennon, G., Copeland, N. G., Gillbert, D. J. Jenkins, N. A., and Zack, D. J. (1997) Neuron 19, 1017-1030; Furukawa, T., Morrow, E. M., and Cepko, C. L. (1997) Cell 91, 531-541). Binding assay and cell culture studies indicate that both PCE-1 and OTX elements and at least two different regulatory factors RX and CRX are necessary for high level, photoreceptor cell-restricted gene expression. Thus, photoreceptor specificity can be achieved by multiple promoter elements interacting with a combination of both photoreceptor-specific regulatory factors and factors present in closely related cell lineages.

Identification of a photoreceptor cell-specific nuclear receptor

Nuclear receptors comprise a large and expanding family of transcription factors involved in diverse aspects of animal physiology and development, the functions of which can be modulated in a spatial and temporal manner by access to small lipophilic ligands and/or the specificity of their own localized expression. Here we report the identification of a human nuclear receptor that reveals a unique proximal box (CNGCSG) in the DNA-binding domain. The conservation of this feature in its nematode counterpart suggests the requirement for this type of P box in the genetic cascades mediated by nuclear receptors in a wide variety of animal species. The expression of this receptor, PNR (photoreceptor-specific nuclear receptor), appears strongly restricted in the retina, exclusively in photoreceptor cells. In human cell lines, PNR expression was observed in Y79 retinoblastoma along with other photoreceptor marker genes such as CRX. Among vertebrate receptors, PNR shares structural kinship with an orphan receptor TLX, and despite distinct differences in the DNA binding domain, PNR is able to recognize a subset of TLX target sequences in vitro. Analyses of the human PNR gene revealed its chromosomal position as 15q24, a site that has recently been reported as a susceptible region for retinal degeneration. These data support a role for PNR in the regulation of signalling pathways intrinsic to the photoreceptor cell function.