Interferon-gamma induces regression of epithelial cell carcinoma: critical roles of IRF-1 and ICSBP transcription factors.

We have developed an epithelial cell carcinoma model for studying efficacy of IFNgamma gene therapy and have identified components of IFNgamma-signaling pathway responsible for its direct anti-tumor actions. The tumor results from ectopic expression of SV40 Large T-Antigen (SV40 T-Ag) oncogene in lens of transgenic mouse (alphaT3) and complete regression of the tumor is induced by targeting expression of IFNgamma into malignant lens cells. Inflammatory cells are absent in lens of alphaT3 or DT (co-expressing IFNgamma and SV40-T-Antigen) mice and the transformed lens cells are non-immunogenic, suggesting non-involvement of immunologic cells. We show that IFNgamma has direct growth-inhibitory effects on tumor cells, induces death of tumor cells by apoptosis and that these effects are mediated by two transcription factors, IRF-1 (interferon-regulatory factor-1) and ICSBP (interferon-consensus sequence-binding protein) induced by IFNgamma. Furthermore, stable transfection with ICSBP or IRF-1 construct inhibits lens carcinoma cell growth by upregulating Caspase-1, p21(WAF1) and p27 expression. In contrast, tumor progression in alphaT3 lens correlates with inhibition of IRF-1 and ICSBP expression. Our results suggest that IFNgamma gene therapy maybe effective in malignant diseases for which DNA tumor viruses are etiologic agents and that antitumor actions of IRF-1/ICSBP can be exploited therapeutically to circumvent adverse clinical effects associated with IFN therapy.

A 76-bp deletion in the Mip gene causes autosomal dominant cataract in Hfi mice.

Hfi is a dominant cataract mutation where heterozygotes show hydropic lens fibers and homozygotes show total lens opacity. The Hfi locus was mapped to the distal part of mouse chromosome 10 close to the major intrinsic protein (Mip), which is expressed only in cell membranes of lens fibers. Molecular analysis of Mip revealed a 76-bp deletion that resulted in exon 2 skipping in Mip mRNA. In Hfi/Hfi this deletion resulted in a complete absence of the wildtype Mip. In contrast, Hfi/+ animals had the same amount of wildtype Mip as +/+. Results from pulse-chase expression studies excluded hetero-oligomerization of wildtype and mutant Mip as a possible mechanism for cataract formation in the Hfi/+. We propose that the cataract phenotype in the Hfi heterozygote mutant is due to a detrimental gain of function by the mutant Mip resulting in either cytotoxicity or disruption in processing of other proteins important for the lens. Cataract formation in the Hfi/Hfi mouse is probably a combined result of both the complete loss of wildtype Mip and a gain of function of the mutant Mip.

The transcription factor Sp3 interacts with promoter elements of the lens specific MIP gene.

PURPOSE: To characterize the cis regulatory elements and their interaction with transcription factors responsible for the lens specific expression of the MIP gene, which encodes the Major Intrinsic Protein of the lens fiber membranes. METHODS: Study interaction of factors present in newborn mouse lens nuclear extracts with DNA fragments corresponding to mouse MIP gene 5' flanking sequence by electrophoresis mobility shift assay (EMSA) and DNase I footprinting. RESULTS: We found a high degree of identity in the first 100 bp of 5' flanking sequence of mice and humans, however, a lower degree of conservation is observed further upstream. We have found by DNase I footprinting analysis that lens specific factors may interact with the first 100 bp of 5' flanking sequence. A domain containing an E box, conserved in mouse and human, may interact with a lens specific factor. However, general factors may interact with a NF-1 binding site. An overlapping GC and CT box is present in the mouse MIP gene. In the human MIP gene GC and CT boxes are found in different domains of the MIP gene promoter. Both CT boxes interact with factors present in lens nuclear extracts including Sp3. They are able to interact with purified Sp1but not with Sp1 present in mouse lens nuclear extracts. CONCLUSIONS: The transcription factor Sp3 may play an important role in regulating MIP gene expression in the lens.

Interferon regulatory transcription factors are constitutively expressed and spatially regulated in the mouse lens.

Interferon regulatory factors (IRFs) are a family of transcription factors involved in regulation of cell growth and immunological responses. Nine IRFs have been described and they are expressed in a variety of cells, except for ICSBP and LSIRF/Pip, which are thought to be expressed exclusively in immune cells. Here, we show that IRF-1, IRF-2, ICSBP, and LSIRF/Pip are constitutively expressed in the mouse lens. These IRFs are present in both the cytoplasm and the nuclei of lens cells. However, the nuclear and cytoplasmic proteins exhibit distinct mobilities on SDS/PAGE. We further show that in the developing mouse lens, IRF-1 and IRF-2 are expressed at high levels in differentiated lens fiber cells with very low and barely detectable levels in undifferentiated lens epithelial cells. Although the level of ICSBP expression is very low in the normal mouse lens, in transgenic mice with constitutive expression of interferon gamma in the lens, its level is markedly elevated and ICSBP expression is detected exclusively in the nuclei of undifferentiated lens cells. Taken together, our data suggest that expression of IRF transcription factors is spatially regulated in the lens and that distinct IRFs may contribute to differential gene regulation in the epithelial and fiber compartments of the vertebrate lens.

Expression of interferon-gamma in the lens exacerbates anterior uveitis and induces retinal degenerative changes in transgenic Lewis rats.

Interferon-gamma (IFN-gamma) is a pleiotropic cytokine that has been implicated in immunopathogenic mechanisms of a number of inflammatory diseases of autoimmune or infectious disease etiology. However, its exact role is still a matter of debate. In experimental mouse models, IFN-gamma has been shown to exacerbate autoimmune thyroiditis, insulin-dependent diabetes mellitus, and autoimmune neuritis while it confers protection against experimental allergic encephalomyelitis and experimental uveitis. In this study, we generated transgenic rats with constitutive expression of IFN-gamma in the eye to study its paracrine effects and to investigate whether local production of IFN-gamma also confers protection against uveitis in the rat species. We show here that chronic exposure of ocular cells to IFN-gamma results in apoptotic death of retinal ganglion cells, development of chronic choroiditis, formation of retinal in-foldings, and activation of proinflammatory genes. In contrast to its protective systemic effect in the mouse, constitutive secretion of IFN-gamma in the rat eye was found to predispose the development of severe anterior uveitis and induction of retinal degenerative processes that impair visual acuity. Our data underscore the danger in extrapolation of cytokine effects in the mouse to humans without corroborating evidence in other species.

Interferon-gamma signaling in human retinal pigment epithelial cells mediated by STAT1, ICSBP, and IRF-1 transcription factors.

PURPOSE: Studies have shown that interferon (IFN)-gamma stimulates expression of intercellular adhesion molecule-1 (ICAM-1), major histocompatibility complex (MHC) class II, interleukin (IL)-6, and inducible nitric oxide synthase and inhibits replication of Toxoplasma gondii in human retinal pigment epithelial (HRPE) cells. The present study was undertaken to investigate the molecular mechanisms of IFN-gamma action. METHODS: RNA, whole-cell extracts, and nuclear extracts were prepared from HRPE cells cultured in the presence or absence of IFN-gamma. Activation of IFN-gamma-responsive genes was analyzed by electrophoretic mobility shift assay, reverse transcription-polymerase chain reaction (RT-PCR), western blot analysis, and immunoprecipitation. RESULTS: HRPE cells constitutively expressed two members of the IFN regulatory factor (IRF) family of transcription factors, IRF-1 and IRF-2. After exposure to IFN-gamma, transcription of IRF-1 and IFN consensus sequence binding protein (ICSBP) genes were induced; IRF-2 gene transcription was not upregulated. Activation of IFN-gamma-responsive genes was mediated by tyrosine phosphorylation of the signal transducer and activator of transcription (STAT)-1 factor. CONCLUSIONS: This study characterized the IFN-gamma signaling pathway in HRPE cells and identified IRF-1, ICSBP, and tyrosine-phosphorylated STAT1 as mediators of IFN-gamma action in these cells. ICSBP is thought to be exclusively used in immunologic responses and has previously been detected only in lymphoid cells. However, the current study shows that ICSBP expression is inducible in HRPE cells, suggesting that it may regulate gene transcription in RPE cells and possibly in other nonimmunologic cell types.

Interferon consensus sequence-binding protein is constitutively expressed and differentially regulated in the ocular lens.

Interferon signaling is mediated by STATs and interferon regulatory factor (IRF) families of transcription factors. Ten distinct IRFs have been described and most are expressed in a variety of cells except for interferon consensus sequence-binding protein (ICSBP) and lymphoid-specific IRF/Pip that are thought to be exclusively expressed in lymphoid cells. We show here for the first time that ICSBP is constitutively and inducibly expressed in the mouse lens. In contrast to lymphoid cells with exclusive expression of ICSBP in the nucleus, ICSBP is present in both the cytoplasm and nucleus of the lens cell. However, ICSBP in the nucleus is of lower apparent molecular weight. We further show that the ICSBP promoter is constitutively bound by lens nuclear factors and that its activation requires binding of additional factors including STAT1. Furthermore, transcriptional activation of ICSBP gene by interferon gamma is accompanied by selective nuclear localization of ICSBP in proliferating epithelial cells but not in the nuclei of nondividing cells in the lens fiber compartment. Constitutive and inducible expression of ICSBP in the ocular lens and differential regulation of its subcellular localization in the developing lens suggest that ICSBP may have nonimmunity related functions and that the commonly held view that it is lymphoid-specific be modified.

IFN-gamma increases the severity and accelerates the onset of experimental autoimmune uveitis in transgenic rats.

Experimental autoimmune uveitis (EAU) is a predominantly Th1-mediated intraocular inflammatory disease that serves as a model for studying the immunopathogenic mechanisms of uveitis and organ-specific autoimmune diseases. Despite the well-documented role of IFN-gamma in the activation of inflammatory cells that mediate autoimmune pathology, recent studies in IFN-gamma-deficient mice paradoxically show that IFN-gamma confers protection from EAU. Because of the implications of these findings for therapeutic use of IFN-gamma, we sought to reexamine these results in the rat, another species that shares essential immunopathologic features with human uveitis and is the commonly used animal model of uveitis. We generated transgenic rats (TR) with targeted expression of IFN-gamma in the eye and examined whether constitutive ocular expression of IFN-gamma would influence the course of EAU. We show here that the onset of rat EAU is markedly accelerated and is severely exacerbated by IFN-gamma. In both wild-type and TR rats, we found that the disease onset is preceded by induction of ICAM-1 gene expression and is characterized by selective recruitment of T cells expressing a restricted TCR repertoire in the retina. In addition, these events occur 2 days earlier in TR rats. Thus, in contrast to the protective effects of IFN-gamma in mouse EAU, our data clearly show that intraocular secretion of IFN-gamma does not confer protection against EAU in the rat and suggest that IFN-gamma may activate distinct immunomodulatory pathways in mice and rats during uveitis.

A novel alternative spliced variant of the transcription factor AP2alpha is expressed in the murine ocular lens.

The AP2alpha gene encodes a transcription factor containing a basic, helix-span-helix DNA-binding/dimerization domain, which is developmentally regulated and retinoic acid inducible. Recent reports about AP2alpha null mice indicate that AP2alpha plays an important role in embryogenesis, especially in craniofacial development and midline fusion. Ocular development is also affected in these null mice. As AP2alpha may be involved in transcriptional regulation in the lens, it was important to examine the expression of the AP2alpha gene in the lens. Four AP2alpha mRNA variants have been previously isolated from whole mouse embryos. Variants 1, 3, and 4 are transcriptional activators that are transcribed from different promoters and variant 2 is a repressor lacking the activation domain encoded by exon 2. Using in situ-PCR, we found that AP2alpha is expressed in the lens epithelia but not in the lens fibers. RT-PCR analysis of lens mRNA with amplimers specific for each variant revealed that AP2alpha variants 1, 2, and 3 are expressed in newborn mouse lenses. However, variant 4 is not expressed in the lens. In this report we characterized a novel isoform, which we named variant 5, expressed in the lens and kidney. Variant 5, which is generated by alternative splicing, may function as a repressor due to the partial deletion of the proline-rich transactivation domain encoded by exon 2. This is the first molecular characterization of AP2alpha gene expression in the lens. Our results indicate that two activator and two repressor AP2alpha isoforms may play a role in regulating gene expression in the lens.

Disregulation of ocular morphogenesis by lens-specific expression of FGF-3/int-2 in transgenic mice.

FGF-3, originally named int-2, was discovered as an oncogene frequently activated in mammary carcinomas resulting from the chromosomal integration of the mouse mammary tumor virus (MMTV). Int-2 was later designated FGF-3 based on sequence homology with other members of the fibroblast growth factor (FGF) family. FGF-1 is the prototypical member of the FGF family, and is the only family member which activates all known FGF receptor isoforms. Transgenic mice expressing in the lens a form of FGF-1 engineered to be secreted show premature differentiation of the entire lens epithelium. In contrast, transgenic mice engineered to secrete FGF-2 in the lens do not undergo premature differentiation of the lens epithelium (C. M. Stolen et al., 1997, Development 124, 4009-4017). To further assess the roles of FGFs and FGF receptors in lens development, the alpha A-crystallin promoter was used to target expression of FGF-3 to the developing lens of transgenic mice. The expression of FGF-3 in the lens rapidly induced epithelial cells throughout the lens to elongate and to express fiber cell-specific proteins including MIP and beta-crystallins. This premature differentiation of the lens epithelium was followed by the degeneration of the entire lens. Since FGF-1 and FGF-3 can both activate one FGF receptor isoform (FGFR2 IIIb) that is not activated by FGF-2, these results suggest that activation of FGFR2 IIIb is sufficient to induce fiber cell differentiation throughout the lens epithelium in vivo. Furthermore, transgenic lens cells expressing FGF-3 were able to induce the differentiation of neighboring nontransgenic lens epithelial cells in chimeric mice. Expression of FGF-3 in the lens also resulted in developmental alterations of the eyelids, cornea, and retina, and in the most severely affected transgenic lines, the postnatal appearance of intraocular glandular structures.

Overlapping Sp1 and AP2 binding sites in a promoter element of the lens-specific MIP gene.

The MIP gene, the founder of the MIP family of channel proteins, is specifically expressed in fiber cells of the ocular lens and expression is regulated temporally and spatially during development. We previously found that a DNA fragment containing 253 bp of 5'-flanking sequence and 42 bp of exon 1 of the human MIP gene contains regulatory elements responsible for lens-specific expression of the MIP gene. In this report we have analyzed the function of overlapping Sp1 and AP2 binding sites present in the MIP promoter. Using DNase I footprinting analysis we found that purified Sp1 and AP2 transcription factors interact with several domains of the human MIP promoter sequence -253/+42. Furthermore, addition of purified Sp1 to Drosophila nuclear extracts activates in vitro transcription from the MIP promoter -253/+42. This promoter activity is competed by oligonucleotides containing domains footprinted with Sp1. Using promoter-reporter gene ( CAT ) constructs we found that the sequence -39/-70 contains a cis regulatory element essential for promoter activity in transient assays in lens cells. EMSA analysis showed that lens nuclear extracts contain factors that bind to the MIP 5'-flanking sequence containing overlapping Sp1 and AP2 binding domains at positions -37/-65. Supershift experiments with lens nuclear extracts indicated that Sp3 is also able to interact with this regulatory element, suggesting that Sp1 and Sp3 may be involved in regulation of transcription of the MIP gene in the lens.

Isolation and characterization of the 5'-flanking sequence of the human ocular lens MIP gene.

The MIP (major intrinsic protein) gene, a member of an ancient family of membrane channel genes, encodes the predominant fiber cell membrane protein of the ocular lens. Its specific expression in the lens fibers is temporally and spatially regulated during development. To study the regulation of expression of MIP and delineate the regulatory elements underlying its tissue specificity and ontogenic profile, we have cloned 2840 bp of the human MIP 5'-flanking sequence. The human MIP 5'-flanking sequence contains three complete Alu repetitive elements in tandem at position between nt -1699 and -2684 (nt -1699/-2684). These Alu elements appear to have had a complex evolutionary history with insertions at different times. We have fused DNA fragments containing MIP 5'-flanking sequences to the bacterial cat reporter gene encoding chloramphenicol acetyltransferase and assayed them in primary cultures of chicken lens cells. We have mapped two negative regulatory regions in the human MIP 5'-flanking sequences -1564/-1696 and -948/-1000. We demonstrated that the human MIP 5'-flanking sequence -253/+42 contains a functional promoter in lens cells but is inactive in kidney epithelial cells or mouse fibroblasts, suggesting that this sequence contains regulatory elements responsible for the lens-specific expression of MIP.

Human AQP2 and MIP genes, two members of the MIP family, map within chromosome band 12q13 on the basis of two-color FISH.

The human AQP2 (collecting duct water channel, aquaporin 2) gene encodes a 271 amino acid protein and is a member of the MIP (major intrinsic protein of lens fiber) gene family. Using two-color fluorescence in situ hybridization on high-resolution R-banded chromosomes and human genomic DNA clones for AQP2 and MIP as probes, we found that both genes mapped closely within the human chromosome region 12q13.

gamma Interferon expression disrupts lens and retinal differentiation in transgenic mice.

We previously generated an animal model for the study of autoimmune diseases of the eye by targeting gamma interferon (gamma IFN) expression to the lens of transgenic mice. Here, we have studied the effect of constitutive lens expression of gamma IFN on eye development of these transgenic mice. By Day 18 of embryonic development, lens and retinal differentiation programs are completely disrupted; normal lens epithelia and fibers are replaced by balloon-like cells and retinal differentiation into inner and outer neuroblastic layers is already affected. The mRNA levels of gamma E- and/or gamma F-crystallin and MIP, markers of lens cell differentiation, are drastically reduced, while expression of ICSBP, a gamma IFN-inducible transcriptional factor, is induced in the alpha ACry-gamma IFN transgenic mouse eyes. Taken together, our results suggest that constitutive expression of gamma IFN and its induction and activation of gamma IFN-inducible transcriptional factors in the eye altered the developmental fate of cells destined to become lens fiber cells by altering the pattern of lens gene expression.

Identification of negative-acting and protein-binding elements in the mouse alpha A-crystallin -1556/-1165 region.

The mouse alpha A-crystallin-encoding gene (alpha A-cry) is expressed in a highly lens-preferred manner. To date, it has been shown that this lens-preferred expression is controlled by four proximal positive-acting transcriptional regulatory elements: DE1 (-111/-97), alpha A-CRYBP1 (-66/-57), PE1/TATA (-35/-19) and PE2 (+24/+43). The present study extends our knowledge of mouse alpha A-cry transcriptional regulatory elements to the far upstream region of that gene by demonstrating that the -1556 to -1165 region contains negative-acting sequence elements which function in transfected lens cells derived from mouse, rabbit and chicken. This is the first negative-acting regulatory region identified in mouse alpha A-cry. The -1556 to -1165 region contains sequences similar to repressor/silencer elements identified in other genes, including those highly expressed in the lens, such as the delta 1-crystallin (delta 1-cry) and vimentin (vim) genes. The -1480 to -1401 region specifically interacts with nuclear proteins isolated from the alpha TN4-1 mouse lens cell line. Contained within this protein-binding region and positioned at -1453 to -1444 is a sequence (RS1) similar to the chicken delta 1-cry intron 3 repressor, and which competes for the formation of -1480 to -1401 DNA-protein complexes. Our findings suggest that lens nuclear proteins bind to the mouse alpha A-cry RS1 region. We demonstrate that the chicken delta 1-cry intron repressor binds similar nuclear proteins in chicken embryonic lens cells and mouse alpha TN4-1 lens cells.(ABSTRACT TRUNCATED AT 250 WORDS)

Ectopic expression of gamma interferon in the eyes of transgenic mice induces ocular pathology and MHC class II gene expression.

PURPOSE: To direct the expression of gamma IFN to the eyes of transgenic mice as a means of investigating the possible role of this lymphokine in ocular pathogenesis. METHODS: Transgenic mouse strains were generated by injection of a DNA fragment containing the murine alpha A-crystallin promoter fused to the coding sequence of murine gamma IFN gene. PCR and RT-PCR were used to screen for the presence of the transgene and mRNA analyses, respectively. Methacrylate-embedded eye sections were analyzed for morphology and cryosections for immunoperoxidase antibody staining. RESULTS: The most notable effects of gamma IFN in these transgenic mice include cataract, microphthalmia, blepharophimosis, microphakia, impairment of lens fiber formation, arrest of retinal differentiation, serous retinal detachment with presence of macrophages in the subretinal space, persistent hyperplastic primary vitreous, and corneal vascularization. MHC class II mRNA levels were significantly increased in the transgenic eyes and MHC class II proteins were expressed in their cornea, iris, ciliary body, choroid, lens and RPE. CONCLUSIONS: Ectopic expression of gamma IFN in the lens affected the growth of the whole eye, resulting in microphthalmia and microphakia. The author's data suggest that alpha ACry-gamma IFN transgenic mouse ocular cells express functional gamma IFN receptors and that interaction of gamma IFN with its receptor induced biochemical and morphologic changes in the transgenic eyes. These mice provide an animal model for the study of the linkage between aberrant MHC expression and predisposition to autoimmune diseases.

Abundant mRNAs in the squid light organ encode proteins with a high similarity to mammalian peroxidases.

A library derived from mRNA in the bacterial light organ of the squid, Euprymna scolopes, contained an unexpectedly high proportion of cDNAs that encode proteins with approximately 30% similarity to a family of mammalian peroxidases (PO) including myelo-PO, eosinophil PO, and thyroid PO (donor:hydrogen-peroxide oxidoreductase; EC 1.11.1.7). Two nearly full-length cDNAs were determined to encode putative PO of nearly 93 kDa each that are 97% identical in amino acid sequence to each other. Each contains four potential glycosylation sites, and His416, believed to be within the active site of the human PO, is conserved in the putative PO from the squid light organ. The mRNAs for the putative squid PO were approximately 250 times more abundant in the tissue housing the bacterial symbiont than in the ocular lens or mantle and were undetectable in the light organ lens. By analogy with the bacteriocidal function of PO in mammalian neutrophils, the putative squid PO may be important for modulating or limiting the population of bacteria within the light organ. The possibility that the squid light organ contains a high concentration of PO raises the possibility that the light organ lens is under oxidative stress, providing a possible rationale for the recruitment of its aldehyde dehydrogenase-like crystallin.

Conservation of mouse alpha A-crystallin promoter activity in chicken lens epithelial cells.

Previous transfection experiments have shown that 162 base pairs (bp) of the 5' flanking sequence of the chicken alpha A-crystallin gene are required for promoter activity in primary chicken lens epithelial cells (PLE), while only 111 bp of the 5' flanking sequence are needed for activity of the mouse alpha A-crystallin promoter in transfected chicken PLE cells or in a SV40 T-antigen-transformed transfected mouse lens epithelial cell line (alpha TN4-1). The effect of site-directed mutations covering positions -111 to -34 of the mouse alpha A-crystallin promoter fused to the bacterial chloramphenicol acetyltransferase (CAT) gene was compared in transfected chicken PLE cells and mouse alpha TN4-1 cells; selected mutations were also examined in a nontransformed rabbit lens epithelial cell line (N/N1003A). In general, the same mutations reduced promoter activity in the transfected lens cells from all three species, although differences were noted. The mutations severely affected regions -111/-106 and -69/-40 regions in all the transfected cells examined; by contrast, mutations at positions -105/-99 and -87/-70 had a somewhat greater effect in the chicken PLE than the mouse alpha TN4-1 cells, while mutations of the -93/-88 sequence reduced expression in the alpha TN4-1 but not the PLE cells. A partial cDNA with sequence similarity to alpha A-CRYPB1 of the mouse has been isolated from a chicken lens library; mouse alpha A-CRYBP1 is a putative transcription factor which binds to the -66/-55 sequence of the mouse alpha A-crystallin promoter.(ABSTRACT TRUNCATED AT 250 WORDS)

The alpha A-crystallin gene: conserved features of the 5'-flanking regions in human, mouse, and chicken.

Approximately 2 kb of 5'-flanking sequences of the lens-specific alpha A-crystallin genes from human and mouse are presented and compared with similar regions of the chicken gene. A repetitive element was found approximately 1 kb upstream from the coding sequences of the alpha A-crystallin gene in all three species (Alu in human, B2 in mouse, and CR1 in chicken), suggesting that they may have an important functional or structural role. Despite the ability of alpha A-crystallin promoters to function across species, dot matrix analyses show only limited similarity among the 600 bp 5' to the structural genes of these three species. The human 5'-flanking sequence is more similar to that of the mouse and chicken than the mouse and chicken are to each other. Numerous short sequences (8-13 bp) are common to all three genes but are distributed differently in each species. The locations and conservation of these sequence motifs suggest functional roles, possibly as cis-regulatory elements of transcription. One motif is similar to the alpha A-CRYBP1 binding site implicated earlier in the transcriptional regulation of the mouse alpha A-crystallin gene, and other motifs correspond to sites previously mapped by methylation interference studies in the mouse alpha A-crystallin promoter. The modular arrangement of conserved sequence motifs is consistent with evolutionary changes occurring at the level of gene regulation.