Epigenetic regulatory mechanisms in vertebrate eye development and disease.

Eukaryotic DNA is organized as a nucleoprotein polymer termed chromatin with nucleosomes serving as its repetitive architectural units. Cellular differentiation is a dynamic process driven by activation and repression of specific sets of genes, partitioning the genome into transcriptionally active and inactive chromatin domains. Chromatin architecture at individual genes/loci may remain stable through cell divisions, from a single mother cell to its progeny during mitosis, and represents an example of epigenetic phenomena. Epigenetics refers to heritable changes caused by mechanisms distinct from the primary DNA sequence. Recent studies have shown a number of links between chromatin structure, gene expression, extracellular signaling, and cellular differentiation during eye development. This review summarizes recent advances in this field, and the relationship between sequence-specific DNA-binding transcription factors and their roles in recruitment of chromatin remodeling enzymes. In addition, lens and retinal differentiation is accompanied by specific changes in the nucleolar organization, expression of non-coding RNAs, and DNA methylation. Epigenetic regulatory mechanisms in ocular tissues represent exciting areas of research that have opened new avenues for understanding normal eye development, inherited eye diseases and eye diseases related to aging and the environment.

Quantitation of PAX6 and PAX6(5a) transcript levels in adult human lens, cornea, and monkey retina.

PURPOSE: PAX6 is a critical regulator of the developing lens, other ocular tissues, central nervous system, and pancreas. There are two alternatively spliced forms of the protein, PAX6 and PAX6(5a), that may have different regulatory functions. This study was designed to determine the amounts of PAX6 and PAX6(5a) transcripts present in adult human lens epithelium and fibers, human cornea and monkey retina. METHODS: PAX6 and PAX6(5a) transcript levels were monitored in microdissected lens epithelia, lens fibers, whole lens, cornea, and retina by competitive RT-PCR. The levels of TBP/TFIID were examined in adult human lens epithelium and fibers as control. RESULTS: PAX6 and PAX6(5a) were expressed at equal levels in lens epithelium and fibers. Ninety-five times more PAX6 transcripts were detected in the epithelial cells than in the fibers. Adult human cornea and monkey retina expressed less PAX6/PAX6(5a) than lens epithelium but more than lens fibers. Correspondingly, 40 fold higher levels of TBP transcripts were detected in lens epithelium than fibers, suggesting reduced overall expression of transcription factors in the adult lens fibers. CONCLUSIONS: The presence of PAX6 and PAX6(5a) messages and proteins in adult lens epithelium suggest functions for both forms of PAX6 in the growth and maintenance of the adult human lens. The reduced levels of both forms of PAX6 in the lens fibers suggest down regulation of this gene during differentiation of epithelia into fibers. The lower level of TBP expression in lens fibers also suggests reduced transcriptional competence of adult lens fibers.

Overexpression of PAX6(5a) in lens fiber cells results in cataract and upregulation of (alpha)5(beta)1 integrin expression.

The PAX6 gene, a key regulator of eye development, produces two major proteins that differ in paired domain structure: PAX6 and PAX6(5a). It is known that an increase in the PAX6(5a) to PAX6 ratio leads to multiple ocular defects in humans. Here, transgenic mice were created that overexpress human PAX6(5a) in the lens. These mice develop cataracts with abnormalities in fiber cell shape as well as fiber cell/lens capsule and fiber cell/fiber cell interactions. While the structure of the actin cytoskeleton appeared relatively normal, the cataractous lens expresses increased amounts of paxillin and p120(ctn) as well as large aggregates of (alpha)5(beta)1 integrin in the dysgenic fiber cells. The elevated amounts of these proteins in the transgenic lens correlated well with elevated levels of their respective mRNAs. To investigate the role of Pax-6(5a) in the upregulation of these genes, a series of gel shift experiments using truncated proteins and consensus oligonucleotides demonstrated the complexity of Pax-6 and Pax-6(5a) binding to DNA, aiding our identification of potential binding sites in the human (&agr;)5- and (beta)1-integrin promoters. Consequent gel shift analysis demonstrated that these putative regulatory sequences bind Pax-6 and/or Pax-6(5a) in lens nuclear extracts, suggesting that the human (alpha)5 and (beta)1 integrin promoters contain PAX6/PAX6(5a) binding sites and maybe directly regulated by this transcription factor in the transgenic lens. We conclude that these transgenic mice are good models to study a type of human cataract and for identifying batteries of genes that are directly or indirectly regulated by both forms of Pax-6.

Regulation of human myocilin/TIGR gene transcription in trabecular meshwork cells and astrocytes: role of upstream stimulatory factor.

BACKGROUND: Mutations in the myocilin (MYOC)/TIGR gene are responsible for autosomal-dominant juvenile primary open-angle glaucoma (POAG). In patients with non-autosomal-dominant POAG, such mutations are rare, but the expression of MYOC/TIGR in the trabecular meshwork (TM) of the eye is considerably higher than in normals. We performed transfection, DNAse I footprinting, mutagenesis and electrophoretic mobility shift assays (EMSA) to identify elements responsible for the basal transcription of MYOC/TIGR in TM cells and astrocytes. RESULTS: DNAse I footprinting experiments of the human MYOC/TIGR promoter showed a major protected area between nt -106 to -77, which was not conserved in the homologous region of the mouse myoc/tigr promoter. In addition, the TATA-box was protected, as well as at least three downstream sites, including an AP-1-like sequence. Deletion of the -106 to -77 region caused a substantial loss of functional promotor activity in all cell types. Site-directed mutagenesis and EMSA experiments revealed the presence of two regulatory elements in the -106 to -77 region. Each of these cis-elements is essential for minimal promoter activity. The 5'-half of the region contains a sequence with similarities to NF-kappaB-related sites, however, binding of NF-kappaB could not be confirmed by EMSA. The 3'-half contains a canonical E-box sequence. EMSA experiments showed that the upstream regulatory factor (USF) was binding to the E-box sequence and that the binding can be supershifted by specific antibodies. CONCLUSIONS: Several DNA-protein binding elements contribute to a transcription of MYOC/TIGR, and USF is critically required for its basal transcription in trabecular meshwork cells and astrocytes.

Truncated forms of Pax-6 disrupt lens morphology in transgenic mice.

PURPOSE: Extensive literature shows that Pax-6 is critical for lens development and that Paxb mutations can result in aniridia in humans. In addition, it has been reported that truncated Pax-6 molecules can act as dominant-negative repressors of wild-type Pax-6 activity in cultured cells. This study was designed to determine whether Pax-6 molecules without either the activation domain (AD) or the homeodomain (HD) and the AD can function as dominant-negative repressors in vivo and alter the phenotype of the lens. METHODS: Transgenic mice were created harboring the alphaA-crystallin promoter linked to a cDNA encoding either a truncated Pax-6 without the C terminus (paired domain [PD] + homeodomain) or Pax-6 consisting of only the PD. The phenotype of the resultant animals was investigated by light and electron microscopy as well as atomic absorption spectroscopy. RESULTS: Two lines of PD + HD mice and three lines of PD mice were generated, all of which exhibit posterior nuclear and/or cortical cataracts of variable severity. The lenses from mice transgenic for either Pax-6 truncation are smaller and more hydrated than normal. Morphologically, the mice expressing the PD + HD of Pax-6 have swollen lens fibers with attenuated ball-and-socket junctions. In contrast, the lenses from mice overexpressing the PD of Pax-6 have posterior nuclear cataracts composed of cell debris, whereas the remaining fiber cells appear generally normal. CONCLUSIONS: The presence of truncated Pax-6 protein in the lens is sufficient to induce cataract in a wild-type genetic background. The simplest explanation for this phenomenon is a dominant-negative effect; however, a number of other possible mechanisms are presented.

Molecular cloning and expression of the human and mouse homologues of the Drosophila dachshund gene.

Recent genetic analysis of the Drosophila dachshund (dac) gene has established that dac encodes a novel nuclear protein that is involved in both eye and leg development. In the Drosophila eye, dac expression appears to be controlled by the product of the eyeless/Pax6 gene. In order to analyze the Pax6 pathway in vertebrates we have isolated and characterized the cDNA and genomic clones corresponding to the human and mouse homologues of Drosophila dac. A full-length human cDNA encoding dachshund (DACH) encodes the 706 amino acids protein with predicted molecular weight of 73 kDa. A 109 amino acid domain located at the N-terminus of the DACH showed significant sequence and secondary structure homologies to the ski/sno oncogene products. Northern blot analysis found human DACH predominantly in adult kidney, heart, and placenta, with less expression detected in the brain, lung, skeletal muscle and pancreas. A panel of human cell lines was studied and most notably a large proportion of neuroblastomas expressed DACH mRNA. Mouse Dach encodes a protein of 751 amino acids with predicted molecular weight of 78 kDa that is 95% identical to the human DACH. RNase protection analysis showed the highest Dach mRNA expression in the adult mouse kidney and lung, whereas lower expression was detected in the brain and testis. RT/PCR analysis readily detected Dach mRNA in the adult mouse cornea and retina. Dach mRNA expression in the mouse E11.5 embryo was observed primarily in the fore and hind limbs, as well as in the somites.

Regulation of alphaA-crystallin gene expression. Lens specificity achieved through the differential placement of similar transcriptional control elements in mouse and chicken.

The lens-preferred mouse alphaA-crystallin gene contains a conserved stretch (proximal element 2, +24/+43) in its 5'-noncoding region that we have previously shown binds nuclear proteins of lens and non-lens cells. The 5'-half of this sequence (PE2A, +25/+32) has consensus binding sites for AP-1 and other transcription factors. We show here by deletion experiments that PE2A is important for activity of the mouse alphaA-crystallin promoter and mediates phorbol ester and c-Jun responsiveness of this promoter in transfected lens cells. In vitro protein binding studies suggest that AP-1 complexes are capable of binding to PE2A. Our findings suggest that PE2A plays a role in mouse alphaA-crystallin gene expression through AP-1-mediated regulatory mechanisms. We propose that the mouse and chicken alphaA-crystallin genes are expressed with lens specificity using a similar assortment of transcription factors but with a different physical arrangement of their respective cis-elements within the promoter region. A fundamental role for AP-1 in lens-preferred expression of crystallin genes is consistent with the idea that a redox-sensitive mechanism is a selective force for recruiting lens crystallins.

Pax-6 interactions with TATA-box-binding protein and retinoblastoma protein.

PURPOSE: To identify proteins that physically interact with Pax-6, a paired domain- and homeodomain (HD)-containing transcription factor that is a key regulator of eye development. METHODS: Protein-protein interactions involving Pax-6, TATA-box-binding protein (TPB), and retinoblastoma protein were studied using affinity chromatography with Pax-6 as ligand, glutathione-S-transferase (GST) pull-down assays, and immunoprecipitations. RESULTS: The authors have shown that Pax-6 is a sequence-specific activator of many crystallin genes, all containing a TATA box, in the lens. Others have shown that lens fiber cell differentiation, characterized by temporally and spatially regulated crystallin gene expression, depends on retinoblastoma protein. In the present study it was shown that Pax-6 interacted with the TBP, the DNA-binding subunit of general transcription complex TFIID. GST pull-down assays indicated that this interaction was mediated by the Pax-6 HD, with a substantial role for its N-terminal arm and first two alpha-helices. The experiments also indicated a binding role for the C-terminal-activation domain of the protein. In addition, the present study showed that the HD of Pax-6 interacted with retinoblastoma protein. Immunoprecipitation experiments confirmed retinoblastoma protein/Pax-6 complexes in lens nuclear extracts. CONCLUSIONS: Blending the present results with those in the literature suggests that Pax-6 and retinoblastoma protein participate in overlapping regulatory pathways controlling epithelial cell division, fiber cell elongation, and crystallin gene expression during lens development.

Dual roles for Pax-6: a transcriptional repressor of lens fiber cell-specific beta-crystallin genes.

It has been demonstrated previously that Pax-6, a paired domain (PD)/homeodomain (HD) transcription factor critical for eye development, contributes to the activation of the alphaB-, alphaA-, delta1-, and zeta-crystallin genes in the lens. Here we have examined the possibility that the inverse relationship between the expression of Pax-6 and beta-crystallin genes within the developing chicken lens reflects a negative regulatory role of Pax-6. Cotransfection of a plasmid containing the betaB1-crystallin promoter fused to the chloramphenicol acetyltransferase reporter gene and a plasmid containing the full-length mouse Pax-6 coding sequences into primary embryonic chicken lens epithelial cells or fibroblasts repressed the activity of this promoter by as much as 90%. Pax-6 constructs lacking the C-terminal activation domain repressed betaB1-crystallin promoter activity as effectively as the full-length protein, but the PD alone or Pax-6 (5a), a splice variant with an altered PD affecting its DNA binding specificity, did not. DNase footprinting analysis revealed that truncated Pax-6 (PD+HD) binds to three regions (-183 to -152, -120 to -48, and -30 to +1) of the betaB1-crystallin promoter. Earlier experiments showed that the betaB1-crystallin promoter sequence from -120 to -48 contains a cis element (PL2 at -90 to -76) that stimulates the activity of a heterologous promoter in lens cells but not in fibroblasts. In the present study, we show by electrophoretic mobility shift assay and cotransfection that Pax-6 binds to PL2 and represses its ability to activate promoter activity; moreover, mutation of PL2 eliminated binding by Pax-6. Taken together, our data indicate that Pax-6 (via its PD and HD) represses the betaB1-crystallin promoter by direct interaction with the PL2 element. We thus suggest that the relatively high concentration of Pax-6 contributes to the absence of betaB1-crystallin gene expression in lens epithelial cells and that diminishing amounts of Pax-6 in lens fiber cells during development allow activation of this gene.

Involvement of retinoic acid/retinoid receptors in the regulation of murine alphaB-crystallin/small heat shock protein gene expression in the lens.

Crystallins are a diverse group of abundant soluble proteins that are responsible for the refractive properties of the transparent eye lens. We showed previously that Pax-6 can activate the alphaB-crystallin/small heat shock protein promoter via the lens-specific regulatory regions LSR1 (-147/-118) and LSR2 (-78/-46). Here we demonstrate that retinoic acid can induce the accumulation of alphaB-crystallin in N/N1003A lens cells and that retinoic acid receptor heterodimers (retinoic acid receptor/retinoid X receptor; RAR/RXR) can transactivate LSR1 and LSR2 in cotransfection experiments. DNase I footprinting experiments demonstrated that purified RAR/RXR heterodimers will occupy sequences resembling retinoic acid response elements within LSR1 and LSR2. Electrophoretic mobility shift assays using antibodies indicated that LSR1 and LSR2 can interact with endogenous RAR/RXR complexes in extracts of cultured lens cells. Pax-6 and RAR/RXR together had an additive effect on the activation of alphaB-promoter in the transfected lens cells. Thus, the alphaB-crystallin gene is activated by Pax-6 and retinoic acid receptors, making these transcription factors examples of proteins that have critical roles in early development as well as in the expression of proteins characterizing terminal differentiation.

A complex enhancer of the chicken beta A3/A1-crystallin gene depends on an AP-1-CRE element for activity.

PURPOSE: To define transcriptional regulatory elements of the chicken beta A3/A1-crystallin gene. METHODS: Reporter genes were made with fragments of the chicken beta A3/A1-crystallin gene fused to the bacterial gene encoding chloramphenicol acetyltransferase (CAT). The reporter plasmids were transfected into primary cultures of chicken-patched lens epithelium or fibroblast cells, and the CAT activity of cellular extracts was measured. The binding of lens nuclear proteins to beta A3/A1 sequences was tested in electrophoretic mobility shift assays. RESULTS: Sequences from -287 to -254 bp relative to the transcriptional start site function as an enhancer in transfected lens and nonlens cells. The length of a T-rich sequence downstream of the enhancer influences its activity. Minimal enhancer activity depends on sequences between -270 and -254 bp, and full activity requires additional upstream sequences. The minimal enhancer includes a consensus sequence (TGAGTCA) for basic region-leucine zipper (bZIP) proteins of the AP-1-CREB superfamily. Lens nuclear proteins bind the enhancer sequences to form several specific complexes, some of which are related antigenically to members of the AP-1 and CREB families of proteins. CONCLUSIONS: An enhancer of the chicken beta A3/A1-crystallin gene between -287 and -254 bp functions in both lens and nonlens cells and binds multiple nuclear proteins. Temporal and spatial regulation of beta A3/A1 expression in the lens may be regulated by the enhancer.

Transcriptional regulation of the mouse alpha A-crystallin gene: binding of USF to the -7/+5 region.

Lens preferred-expression of the mouse alpha A-crystallin gene (alpha A-cry) is regulated at the transcriptional level by multiple elements located in the 5' flanking region of the gene. Here we present the first analysis of the functional role of the mouse alpha A-cry +1 region and the protein(s) which bind to it. The -7/+5 region of this promoter exhibits sequence similarity with the consensus upstream stimulating factor (USF) transcription factor binding site. A wild type oligodeoxyribonucleotide (oligo) spanning the mouse alpha A-cry -15/+15 region specifically inhibited the activity of a mouse alpha A-cry promoter-cat gene fusion (p alpha A 111aCAT) in competitive co-transfection studies in the mouse alpha TN4-1 lens cell line, as did an oligo containing the adenovirus 2 major late promoter strong USF binding site. In contrast, an alpha A-cry oligo mutated (-3/+3) within the USF-like binding site did not inhibit p alpha A111aCAT activity. Western blot analysis indicated that alpha TN4-1 cells express USF1. Co-transfection of p alpha A111aCAT and a USF1 cDNA expression vector into alpha TN4-1 cells resulted in a repression of mouse alpha A-cry promoter activity. Electrophoretic mobility shift analyses (EMSA) demonstrated that proteins in an alpha TN4-1 nuclear extract form a single major complex on synthetic oligos spanning the mouse alpha A-cry -15/+15 region. The formation of this complex was inhibited by the presence of unlabeled -15/+15 oligos or an anti-USF1 antibody. In addition, purified USF1 bound to this region, producing a complex similar in size to that observed with alpha TN4-1 nuclear extracts. Taken together, our findings show that USF can bind to the mouse alpha A-cry +1 site, and support the possibility that USF plays a role in promoter activity of this gene. Sequence similarities surrounding the +1 region of the alpha A-cry gene of the mouse, mole rat, hamster, and human, as well as the previously observed utilization of USF by different cry promoters suggest that USF contributes to the high expression of many crys in the ocular lens of diverse species.

Lens-preferred activity of chicken delta 1- and delta 2-crystallin enhancers in transgenic mice and evidence for retinoic acid-responsive regulation of the delta 1-crystallin gene.

There are two tandemly linked delta-crystallin genes [5' delta 1 -delta 2 3'] in the chicken, with the delta 1-crystallin gene being expressed much more highly (50-100-fold) in the embryonic lens than the delta 2-crystallin gene. Previous transfection experiments have shown that a lens-preferred enhancer exists in the third intron of each chicken delta-crystallin gene. In the present investigation we have used transgenic mice to establish that both the chicken delta 1- and delta 2-crystallin enhancers are preferentially active in the mouse lens in combination with their homologous promoter and the chloramphenicol acetyltransferase (CAT) reporter gene. The promoter/ CAT constructs lacking the enhancers were inactive in the transgenic mice. In one case, a truncated delta 2-crystallin promoter (-308/+24) in combination with the enhancer was also active in the Purkinje cells of the cerebellum of the transgenic mice, which could prove useful in future experiments. Finally, retinoic acid receptors (RAR beta) activated the delta 1-crystallin, but not the delta 2-crystallin enhancer in teh recombinant plasmids in cotransfected embryonic chicken lens epithelial cells treated with retinoic acid. This activation did not occur when using the care enhancer (fragment B4) lacking surrounding flanking sequences (fragment B3 and B5) of the enhancer. Together these experiments show that the chicken delta-crystallin enhancers show lens-preference in transgenic mice despite the absence of delta-crystallin in this species and add retinoic acid nuclear receptors to the growing list of transcription factors (including Pax-6, Sox-2, and delta EF3) that directly or indirectly contribute to the high expression of the delta 1-crystallin gene in the lens.

Pax-6 and alphaB-crystallin/small heat shock protein gene regulation in the murine lens. Interaction with the lens-specific regions, LSR1 and LSR2.

We have demonstrated previously that a transgene comprising the -164/+44 fragment of the murine alphaB-crystallin gene fused to the bacterial chloramphenicol acetyltransferase (cat) gene is lens-specific in transgenic mice. The -147 to -118 sequence was identified as a lens-specific regulatory region and is called here LSR1 for lens-specific region 1. In the present experiments, a -115/+44-cat transgene was also lens-specific in transgenic mice, although the average activity was 30 times lower than that derived from the -164/+44-cat transgene. The -115/+44 alphaB-crystallin fragment contains a highly conserved region (-78 to -46) termed here LSR2. A -68/+44-cat transgene, in which LSR2 is truncated, was inactive in transgenic mice. DNase I footprinting indicated that LSR1 and LSR2 bind partially purified nuclear proteins from either alphaTN4-1 lens cells or the mouse lens as well as the purified paired domain of Pax-6. Site-specific mutation of LSR1 eliminated both Pax-6 binding and promoter activity of the -164/+44-cat transgene in transgenic mice. Finally antibody/electrophoretic mobility shift assays and cotransfection experiments indicated that Pax-6 can activate the alphaB-crystallin promoter via LSR1 and LSR2. Our data strengthen the idea that Pax-6 has had a major role in recruiting genes for high expression in the lens.

Lens development and crystallin gene expression: many roles for Pax-6.

The vertebrate eye lens has been used extensively as a model for developmental processes such as determination, embryonic induction, cellular differentiation, transdifferentiation and regeneration, with the crystallin genes being a prime example of developmentally controlled, tissue-preferred gene expression. Recent studies have shown that Pax-6, a transcription factor containing both a paired domain and homeodomain, is a key protein regulating lens determination and crystallin gene expression in the lens. The use of Pax-6 for expression of different crystallin genes provides a new link at the developmental and transcriptional level among the diverse crystallins and may lead to new insights into their evolutionary recruitment as refractive proteins.

Lens-specific expression of a chicken beta A3/A1-crystallin promoter fragment in transgenic mice.

Beta A3/A1-crystallin is one of the major refractive proteins of the chicken eye lens. Previously we showed that a fragment from -382 to +22 bp of the beta A3/A1-crystallin gene functions as a promoter in transfected lens cells. Here we show by use of the bacterial chloramphenicol acetyltransferase reporter gene that the -143/+22 fragment is sufficient for lens-specific promoter activity in transgenic mice. DNase I footprinting shows that lens nuclear proteins protect several regions within the minimal promoter fragment.

Sequence, initial functional analysis and protein-DNA binding sites of the mouse beta B2-crystallin-encoding gene.

An 800-bp fragment of genomic DNA upstream from the origin of transcription of the mouse beta B2-crystallin-encoding gene (beta B2-Cry) has been isolated and its nucleotide sequence determined. Promoter fragments 275 to +30 or -110 to +30, fused to cat reporter gene, activated transcription in transiently transfected rabbit lens epithelial cells, but not in various non-lens cells. The beta B2-Cry mouse promoter contains a typical TATA-box located approx. 25 bp upstream from the transcription start point. Binding sites (upstream from the TATA-box) for transcription factors possibly involved in the regulation of gene expression have been identified by DNaseI footprinting analysis and lens cell nuclear extracts. Most notably is the binding of the Pax-6 paired domain (PrD) which correlates with the binding of lens cell nuclear proteins at the -80 to -40 region.

Transactivation of the human T-cell lymphotropic virus type 1 Tax1-responsive 21-base-pair repeats requires Holo-TFIID and TFIIA.

The human T-cell lymphotropic virus type 1 (HTLV-1) is the etiological agent for adult T-cell leukemia and tropical spastic paraparesis/HTLV-1-associated myelopathy. The HTLV-1 Tax1 gene product has been shown to transactivate transcription of viral and cellular promoters. To examine the biochemical mechanism of Tax1 transactivation, we have developed an in vitro transactivation assay in which wild-type Tax1 is able to specifically transactivate a polymerase II promoter through upstream Tax1-responsive elements. The in vitro system utilizes the HTLV-1 21-bp repeats cloned upstream of the ovalbumin promoter and G-free cassette. Purified Tax1 specifically transactivates this template 5- to 10-fold in a concentration-dependent manner. No transactivation of the ovalbumin promoter (pLovTATA) template control was observed. Tax1 transactivation was inhibited by low concentrations of alpha-amanitin and was effectively neutralized by anti-Tax1 but not control sera. Consistent with in vivo transactivating activity, Tax1 NF-kappa B mutant M22, but not cyclic AMP-responsive element-binding protein mutant M47, transactivated the template containing the tandem 21-bp repeat. In a reconstituted in vitro transcription assay, Tax1 transactivation was dependent upon basal transcription factors TFIIB, TFIIF, Pol II, TFIID, and TFIIA. TATA-binding protein did not functionally substitute for TFIID in the transactivation assay by Tax1 but was sufficient for basal transcription. Finally, we have used anti-TFIIA antibody (p55) to ask if Tax1 transactivation required TFIIA activity. Addition of TFIIA antibody to in vitro transcription reactions, as well as depletion of TFIIA by preclearing with antibody, showed that TFIIA was required for Tax1 transactivation. Only a slight (twofold) drop of basal transcription was observed. Tax1 transactivation was restored when purified HeLa TFIIA was added back into the reconstituted system. We propose that Tax1 utilizes a transactivation pathway involving the activator regulated basal transcription factors TFIID and TFIIA.

Pax-6 is essential for lens-specific expression of zeta-crystallin.

Pax-6 is essential for normal eye development and has been implicated as a "master gene" for lens formation in embryogenesis. Guinea pig zeta-crystallin, a taxon-specific enzyme crystallin, achieves high expression specifically in lens through use of an alternative promoter. Here we show that Pax-6 binds a site in this promoter, which is essential for lens-specific expression. Lens and lens-derived cells exhibit a tissue-specific pattern of alternative splicing of Pax-6 transcripts and Pax-6 is expressed in adult lenses and cells that support zeta-crystallin expression. These results suggest that zeta-crystallin is a natural target gene for Pax-6 and that this Pax family member has a direct role in the continuing expression of tissue-specific genes.