Primary structure and lens-specific expression of genes for an intermediate filament protein and a beta-tubulin in cephalopods

Intermediate filament (IF) protein and tubulin cDNAs of cephalopod eye lenses were cloned and sequenced. The rod regions of the deduced IF proteins of the squid and octopus were more similar (68% identical) than were head (33% identical) and tail (40% identical) regions. The rod sequences were closer to squid neuronal IF protein (39% identical) than to any other known IF protein. There was only 31% identity between the rod regions, 21-30% identity between the head regions and 23-32% identity between the tail regions of the present IF proteins of cephalopods and other invertebrates. The rod regions of the cephalopod IF proteins contained the 6 heptads characteristic of nuclear lamins, consistent with an evolutionary relationship between IF proteins and lamins. The present octopus alpha-tubulin was 93% and beta-tubulin was 87% identical to the corresponding tubulins of insects and vertebrates. SDS-PAGE and peptide sequencing indicated that the order of abundance of the cephalopod lens cytoskeletal proteins was IF proteins, actin and tubulins. Northern blot hybridization revealed a 4 kb mRNA for the octopus IF protein and 2.9 and 7.3 kb mRNAs for the squid IF protein; the alpha-tubulin mRNA was about 1.8 kb in the octopus and squid, and the beta-tubulin mRNA was about 2.8 kb in the octopus. The alpha-tubulin mRNA was present in all tissues examined; by contrast, the present beta-tubulin and IF protein mRNAs appeared specialized for lens expression.

The murine alpha B-crystallin/small heat shock protein enhancer: identification of alpha BE-1, alpha BE-2, alpha BE-3, and MRF control elements

The murine alpha B-crystallin gene (a member of the small heat shock protein family) is expressed constitutively at high levels in the lens and at lower levels in many other tissues, including skeletal muscle. We have previously used the herpes simplex virus thymidine kinase promoter fused to the human growth hormone gene to identify an alpha B-crystallin enhancer at positions -427 to -259 that has high activity in muscle and low activity in lens cell lines. In the study reported here, we performed DNase I footprinting, transfection, mutagenesis, and electrophoretic mobility shift experiments using the murine C2C12 muscle and alpha TN4-1 lens cell lines and the rabbit N/N1003A lens cell line to identify sequences responsible for activity of this enhancer. Enhancer activity in both the muscle and lens cells was dependent on novel elements called alpha BE-1 (-407 to -397), alpha BE-2 (-360 to -327), and alpha BE-3 (-317 to -306). These elements were also weakly occupied by nuclear proteins in L929 cells, which appear to express the alpha B-crystallin gene at a very low level (detectable only by the polymerase chain reaction). A fourth element containing a consensus muscle regulatory factor-binding site called MRF (-300 to -288) was occupied and used only by the C2C12 muscle cells. Cotransfection in NIH 3T3 cells and antibody-gel shift experiments using C2C12 nuclear extracts indicated that MyoD, myogen, or a similar member of this family can activate the alpha B-crystallin enhancer by interaction with the MRF site. Taken together, we conclude that the alpha BE-1, alpha BE-2, and alpha BE-3 elements are shared by both lens and muscle cells, but the MRF element is used only in muscle cells, providing the first example of a muscle-specific control element in a crystallin gene.

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.

Binding of tissue-specific forms of alpha A-CRYBP1 to their regulatory sequence in the mouse alpha A-crystallin-encoding gene: double-label immunoblotting of UV-crosslinked complexes

The alpha A-CRYBP1 regulatory sequence (alpha A-CRYBP1RS), at nucleotides -66 to -57 of the mouse alpha A-crystallin-encoding gene (alpha A-CRY) promoter, is an important control element involved in the regulation of mouse alpha A-CRY expression. The gene encoding a protein (alpha A-CRYBP1) that specifically binds to the alpha A-CRYBP1RS sequence has been cloned from a cultured mouse lens cell line. In the present study, we have used an antibody (specific to the alpha A-CRYBP1 protein and made against a synthetic peptide) to directly identify UV-crosslinked protein-DNA complexes via a double-label immunoblotting technique. Multiple alpha A-CRYB1 antigenically related proteins interacted with alpha A-CRYBP1RS in nuclear extracts from both a cloned mouse lens cell line (alpha TN4-1) that expresses alpha A-CRY and a mouse fibroblast line (L929) that does not express the gene. Two sizes (50 kDa and 90 kDa) of proteins reacting with the alpha A-CRYBP1-specific Ab were detected in both cell lines and, in addition, a > 200-kDa protein reacting with the Ab was unique to the fibroblast line. Thus, alpha A-CRYBP1 antigenically related proteins interact with alpha A-CRYBP1RS regardless of alpha A-CRY expression. Moreover, differential processing of the alpha A-CRYBP1 protein and/or alternative splicing of the alpha A-CRY transcript may affect expression of alpha A-CRY.

Functional analysis of chicken vimentin distal promoter regions in cultured lens cells

Synthesis of the cytoskeletal intermediate filament protein vimentin (Vim) in the lens is unexpected due to the mesenchymal preference of Vim-encoding gene (Vim) expression and the epithelial origin of the lens. Previous studies indicated that chicken Vim gene expression in cultured lens cells is regulated by both positive- and negative-acting sequence elements within the first -767 nucleotides (nt) of its promoter. Here, we demonstrate the existence of additional upstream chicken Vim promoter elements which function in transfected lens cells. Sequences within the nt -1360/-1156 region repressed promoter activity in transfected lens cells to levels lower than that observed for the previously defined more proximal repressor elements. The -1612/-1360 region activated promoter activity to levels similar to those observed for the strongest previously defined proximal promoter. The nt sequence analysis of the upstream promoter region revealed the presence of multiple consensus repressor and activator transcription-factor-binding sites. Several of these sites have been implicated for lens expression of enzyme-crystallin-encoding genes (cry), suggesting that Vim expression may share features with the cry genes for recruitment and high-level expression in the lens.

Functional redundancy of the DE-1 and alpha A-CRYBP1 regulatory sites of the mouse alpha A-crystallin promoter

Previous studies have implicated the DE-1 (-111/-106) and alpha A-CRYBP1 (-66/-57) sites for activity of the mouse alpha A-crystallin promoter in transiently transfected lens cells. Here we have used the bacterial chloramphenicol acetyltransferase (CAT) reporter gene to test the functional importance of the putative DE-1 and alpha A-CRYBP1 regulatory elements by site-specific and deletion mutagenesis in stably transformed alpha TN4-1 lens cells and in transgenic mice. FVB/N and C57BL/6 x SJL F2 hybrid transgenic mice were assayed for CAT activity in the lens, heart, lung, kidney, spleen, liver, cerebrum, and muscle. F0, F1, and F2 mice from multiple lines carrying single mutations of the DE-1 or alpha A-CRYBP1 sites showed high levels of CAT activity in the lens, but not in any of the non-lens tissues. By contrast, despite activity of the wild-type promoter, none of the mutant promoter/CAT constructs were active in the transiently transfected and stably transformed lens cells. The mice carrying transgenes with either site-specific mutations in both the DE-1 and alpha A-CRYBP1 sites or a deletion of the entire DE-1 and part of the alpha A-CRYBP1 site (-60/+46) fused to the CAT gene did not exhibit CAT activity above background in any of the tissues examined, including the lens. Our results thus indicate that the DE-1 and alpha A-CRYBP1 sites are functionally redundant in transgenic mice. Moreover, the present data coupled with previous transfection and transgenic mouse experiments suggest that this functional redundancy is confined to lens expression within the mouse and is not evident in transiently transfected and stably transformed lens cells, making the cultured lens cells sensitive indicators of functional elements of crystallin genes.

J1-crystallins of the cubomedusan jellyfish lens constitute a novel family encoded in at least three intronless genes

The transparent cellular eye lens of the jellyfish (Tripedalia cystophora) contains three major proteins called J1-, J2-, and J3-crystallins. Here we have isolated cDNAs encoding three novel 37-kDa J1-crystallin polypeptides (J1A, J1B, and J1C) sharing 84-98% identity in amino acid sequence among themselves. Each polypeptide is encoded in a separate gene lacking introns. In contrast to the striking similarity of the coding regions, the 5'- and 3'-untranslated sequences of the three J1-crystallin mRNAs are completely different, consistent with an ancient duplication of their genes. Thermostability experiments showed that J1-crystallins remain soluble at 50 degrees C, but precipitate at 60 degrees C, suggesting that these major lens proteins are neither heat shock proteins nor unusually heat-resistant as are many vertebrate crystallins. Although J1 mRNAs appear polyadenylated, no typical polyadenylation signal was detected in the cDNAs. Surprisingly, the only obvious similarities among the 5'-flanking regions of the three J1-crystallin genes are putative TATA boxes and several CAAT sequences, consistent with fewer evolutionary constraints on the regulatory sequences than on the coding sequences of these crystallin genes.

Aldehyde dehydrogenase-derived omega-crystallins of squid and octopus. Specialization for lens expression

omega-Crystallin of the octopus lens is related to aldehyde dehydrogenases (ALDH) of vertebrates (Tomarev, S. I., Zinovieva, R. D., and Piatigorsky, J. (1991) J. Biol. Chem. 266, 24226-24231) and ALDH1/eta-crystallin of elephant shrews (Wistow, G., and Kim, H. (1991) J. Mol. Evol. 32, 262-269). Only very low amounts of omega-crystallin are present in the squid lens. Here, we have cloned omega-crystallin cDNAs of the octopus (Octopus dofleini) and squid (Ommastrephes sloani pacificus) lenses. The deduced amino acid sequences of omega-crystallin from these species are 78% identical to each other, 56-58% identical to cytoplasmic ALDH1 and mitochondrial ALDH2 of vertebrates (which are 66-68% identical to each other), and 40% identical to Escherichia coli and spinach ALDHs. These data are consistent with the idea that the ALDH1/ALDH2 gene duplication in vertebrates occurred after divergence of cephalopods from the line giving rise to vertebrates, but before the separation of squid and octopus. Southern blot hybridization indicated that omega-crystallin is encoded by few genes (possibly just one) in octopus and squid. Northern blot hybridization revealed two bands (2.7 and 9.0 kilobases) of omega-crystallin RNA in the octopus lens and one band (4.2 kilobases) in the squid lens; omega-crystallin RNAs were undetectable in numerous non-lens tissues of octopus and squid, suggesting lens-specific expression of this gene(s). Finally, extracts of the octopus lens had no detectable ALDH activity using different substrates, consistent with omega-crystallin having no enzymatic activity. Taken together, our results suggest that omega-crystallin evolved by duplication of an ancestral gene encoding ALDH and subsequently specialized for refraction in the transparent lens while losing ALDH activity and expression in other tissues.

Puzzle of crystallin diversity in eye lenses

Crystallins have evolved by various mechanisms that are associated with high expression of their genes in the eye lens. The diversity and pattern of crystallins among different species indicate that independent events have occurred at the molecular level during the evolution of the lens in different invertebrates (jellyfish, squid, and octopus) and vertebrates. Although it is possible that different crystallins are needed to fulfill the specific needs of individual species, the unexpectedly large array of proteins that function as crystallins and their abundance in the lens raise the possibility that selective pressures optimizing the function of certain transcription factors in the lens contribute to the recruitment of crystallins.

Functional elements DE2A, DE2B, and DE1A and the TATA box are required for activity of the chicken alpha A-crystallin gene in transfected lens epithelial cells

alpha A-crystallin is an abundant soluble protein of the vertebrate eye lens. In addition to the TATA box, four positive cis-regulatory elements of the chicken alpha A-crystallin gene have been identified by linker scanning mutagenesis, DNase I footprinting, and gel mobility shift experiments. The regulatory elements described here have been named DE2A (at positions -144 to -134), DE2B (at positions -128 to -118), and DE1A (at positions -114 to -103). DE2A and DE2B form a dyad of symmetry between positions -141 and -118 (5'-AGACTGTCAT....AGGTCAGTCT-3'), consistent with the close similarity in the mobility of complexes formed with lens nuclear proteins by these two elements. Mutations in DE2A, DE2B, and DE1A leading to loss of promoter activity using the bacterial chloramphenicol acetyltransferase reporter gene transfected into primary embryonic chicken lens epithelial cells resulted in a corresponding loss in the ability to compete for complex formation with lens nuclear proteins in gel mobility shift assays. Mutation of the alpha A-CRYBP1-like site (-67/-57), necessary for function of the mouse alpha A-crystallin promoter, did not affect the activity of the chicken promoter. The DNase I footprinting and gel mobility shift experiments confirmed the previously noted binding of nuclear proteins to a dyad of symmetry at positions -153 to -140. In contrast to DE2A, DE2B, and DE1A, mutagenesis and gel mobility shift experiments failed to correlate function and protein binding for the -153/-140 dyad. DE2A, DE2B, and DE1A agree well with the regulatory elements alpha CE1 (-162/-134), alpha CE3 (-135/-121), and alpha CE2 (-119/-99) (Matsuo, I., and Yasuda, K. (1992) Nucleic Acids Res. 20, 3701-3712) for this gene. The present results suggest, however, that the lens enhancer activity of alpha CE1 is due to the sequence -141/-134, which forms the upper half of the DE2A/DE2B dyad of symmetry, rather than the -153/-140 dyad as previously suspected.

Protein-DNA interactions of the mouse alpha A-crystallin control regions. Differences between expressing and non-expressing cells

Genomic footprinting, in vitro footprinting and mobility shift assays were used to investigate the molecular basis for expression of mouse alpha A-crystallin, a major structural protein of the transparent lens of vertebrates. The putative control region of the mouse alpha A-crystallin gene was footprinted by DNase I digestion in nuclear extracts, by dimethylsulfate treatment in cultured cells, and by micrococcal nuclease digestion in isolated nuclei. The resulting digestion patterns were compared between alpha TN4-1 lens cells, which express alpha A-crystallin, and L929 fibroblasts, which do not express alpha A-crystallin. Four regions of DNA were found occupied in both cell types. These included positions -111 to -97 (DE-1 region), positions -75 to -55 (alpha A-CRYBP1 region), positions -35 to -12 (TATA box and PE-1 region), and positions +23 to +43 (an AP-1 consensus sequence). The DNase I footprints of the DE-1 and alpha A-CRYBP1 regions, previously implicated as functional control elements, were substantially more pronounced using nuclear extract from the alpha TN4-1 cells than from the L929 fibroblasts, suggesting more stable protein binding with the former than with the latter. Numerous in vivo binding variations were noted between the two cell types in all four of the footprinted regions examined. Finally, two complexes (A and B) were formed specifically with nuclear extracts from the alpha TN4-1 cells and a synthetic deoxyoligonucleotide comprising the alpha A-CRYBP1 region. These data indicate that specific differences in protein-DNA interactions with putative control regions are associated with tissue-preferred expression of the mouse alpha A-crystallin gene.

Cloning and characterization of a novel zinc-finger protein-encoding cDNA from the mouse eye lens

Zinc fingers (Zf) are a common structural motif found in many nucleic acid-binding proteins. In an effort to identify potential transcription factors in the mouse eye lens, we have isolated a Zf-containing clone from a newborn mouse lens cDNA library. The clone, named pMLZ-4, is 4.5 kb in length and contains an open reading frame of 1073 bp. The putative pMLZ-4 protein consists of a short, N-terminal acidic domain followed by twelve tandemly arrayed Zf of the C2H2 variety. The remaining 3.2 kb of the cDNA comprises the 3'-untranslated region. PCR analysis detected the presence of pMLZ-4 RNA in liver, heart, kidney, spleen and brain of newborn mice. Hybridization of pMLZ-4 to genomic DNA from a number of species of vertebrates revealed the presence of homologous sequences only in mouse and rat. Unexpectedly, the probe also hybridized to a single band in yeast DNA digested with EcoRI. NIH3T3 cells were stably transformed with a construct that over-expresses the pMLZ-4 mRNA. The stably transformed cells did not differ in appearance from untransformed cells, and an analysis of proteins from transformed and untransformed cells failed to detect any differences resulting from over-expression of the pMLZ-4 mRNA.

Squid glutathione S-transferase. Relationships with other glutathione S-transferases and S-crystallins of cephalopods

Glutathione S-transferase (GST, EC 2.5.1.18) was purified from the digestive gland of the squid Ommastrephes sloani pacificus. It had high enzymatic activity for the 1-chloro-2,4-dinitrobenzene substrate and was composed of a major and a minor polypeptide band, both with molecular masses near 25 kDa on SDS-polyacrylamide gels. GST cDNA clones were derived from the digestive gland mRNA. The deduced GSTs of the longest cDNAs (pGST5 and pGST11) containing the entire coding sequence have a molecular mass near 23 kDa. Sequence comparisons showed that the squid GST is 42-44% identical to both squid and octopus S-crystallins (the major proteins of the lens), 32-34% identical to class pi and 29-32% identical to class alpha GSTs of vertebrates, and 19-23% identical to other GSTs of vertebrates and insects. Northern blot hybridization revealed that GST mRNAs were much more abundant in the digestive gland than in the testis, mantle, or lens. Analysis of a squid GST gene indicated that it has an exon-intron structure similar to that of the vertebrate class pi GST gene. An apparently novel repetitive element was identified in the 5'-flanking sequence of the squid GST gene. Our results suggest that multiple duplications of an ancestral GST gene gave rise to a family of enzymatically inactive crystallins specialized for lens refraction and one (or two) active GST enzyme expressed preferentially, but not exclusively, in the digestive gland in squids. This differs from the innovation of refractive function from a metabolic enzyme by increased expression in the lens with minimal or no gene duplication, as occurred among the enzyme-crystallins of vertebrates.

Differential expression of the two delta-crystallin genes in lens and non-lens tissues: shift favoring delta 2 expression from embryonic to adult chickens

Chicken argininosuccinate lyase (ASL)/delta-crystallin, a lens enzyme-crystallin, is encoded in two linked genes (delta 1 and delta 2); only the delta 2 polypeptide contains ASL activity. Here we have quantified delta 1- and delta 2-crystallin mRNA in the lens, cornea, neural retina, heart, and brain at different stages of embryonic development and in 1-wk-old and 1-yr-old chickens by the polymerase chain reaction using internal delta 1 and delta 2 RNA standards. The delta 1/delta 2 mRNA ratio differed for every tissue and was regulated during development. In the embryo there was more delta 1 than delta 2 mRNA in the lens (50-100 times), cornea (3-4 times), and neural retina (2-20 times), about equal amounts of delta 1 and delta 2 mRNA in the heart, and more delta 2 mRNA in the brain (15 times). delta 1-Crystallin mRNA differentially decreased in every tissue after hatching; by contrast, the delta 2 mRNA remained about the same except for the lens, where it decreased 50-fold between 1 wk and 1 yr after hatching. In the 1-yr-old chicken, the delta 2/delta 1 mRNA ratios were 7 in the lens, 175 in the cornea, 22 in the neural retina, 107 in the heart, and 136 in the brain, indicating that delta 2-crystallin is strongly favored in all adult tissues of the chicken. The excess of delta 1 to delta 2 mRNA in the embryonic lens, cornea, and neural retina is intriguing, and suggests some connection with developing transparent eye tissues. Finally, we raise the possibility that expression of both delta-crystallin genes may create tetrameric ASL isoenzymes (perhaps with different specific activities). The unexpected predominance of delta 2 mRNA in the 1-yr-old lens suggests that both the enzymatic and refractive functions of ASL/delta-crystallin are operative and spatially separated, with the enzymatic role present in the cortical fibers and the refractive role in the center of the lens.

The twelfth Frederick H. Verhoeff Lecture: gene sharing in the visual system

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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)

Structure and lens expression of the gene encoding chicken beta A3/A1-crystallin

The beta A1- and beta A3-crystallins are major polypeptides in the lenses of vertebrates. We present evidence that a single beta A3/A1 gene encodes these two proteins in the chicken. The beta A3/A1 gene has been sequenced and its functional promoter identified in transfection experiments. The chicken beta A3/A1 gene has the same structure as the human orthologue: six exons with standard splice sites and two alternative start codons from which the protein products are apparently translated. Northern analysis revealed an abundant 0.9-kb transcript in the lenses of 1-2-day-old chickens and no detectable transcripts in the rest of the eye, brain, heart, kidney, liver or skeletal muscle. The 5'-flanking sequence of the chicken beta A3/A1 gene is very similar to that of the human and mouse genes, suggesting conservation of important putative regulatory sequences in addition to the TATA box. A thymidine-rich element (bp -218 to -163) and a potential AP-1-binding site (bp -264 to -258) are present within the chicken 5'-flanking region. A DNA fragment from -382 to +22 of the chicken beta A3/A1 gene is sufficient to promote expression of the bacterial cat gene in transfected chicken primary lens epithelial cells, but not in transfected dermal fibroblasts.(ABSTRACT TRUNCATED AT 250 WORDS)