Digitalis and digitalislike compounds down-regulate gene expression of the intracellular signaling protein 14-3-3 in rat lens.

Na+,K+-ATPase activity in the epithelial layer is fundamental to the maintenance of ionic concentration gradients and transparency of the lens. Recently we have identified endogenous digitalislike compounds (DLC), 19-norbufalin and its peptide derivatives, in human cataractous lenses (Lichtstein et al. Eur J Biochem 216: 261-268, 1993). Lenses were treated with 10 nM ouabain, bufalin or 19-norbufalin derivative for 24 h and were compared to control lenses. Differential display analysis revealed that one of the down-regulated genes was 14-3-3 theta. Down-regulation was confirmed by Northern blot and by RT-PCR analysis. RT-PCR of additional 14-3-3 isoforms revealed that the eta and gamma isoforms of 14-3-3 are also down-regulated by ouabain, bufalin and 19-norbufalin derivative, whereas the zeta isoform is down-regulated only by bufalin. These results demonstrate that one of the consequences of Na+,K+-ATPase inhibition by exogenous or endogenous inhibitors is the down-regulation of mRNA transcripts encoding several isoforms of 14-3-3. Since the 14-3-3 proteins are multifunctional regulatory proteins, the reduction in the abundance of various isoforms will have profound effects on cell function. Furthermore, These results, together with the demonstration of digitalislike compounds in the normal lens, and their increased level in human cataractous lenses, strongly suggests their involvement in the molecular mechanisms responsible for cataract formation.

Molecular modeling of the aldose reductase-inhibitor complex based on the X-ray crystal structure and studies with single-site-directed mutants.

Aldose reductase (AR) has been implicated in the etiology of the secondary complications of diabetes. This enzyme catalyzes the reduction of glucose to sorbitol using nicotinamide adenine dinucleotide phosphate as an essential cofactor. AR has been localized at the sites of tissue damage, and inhibitors of this enzyme prevent the development of neuropathy, nephropathy, retinopathy, and cataract formation in animal models of diabetes. The crystal structure of AR complexed with zopolrestat, a potent inhibitor of AR, has been described.(1) We have generated a model of the AR-inhibitor complex based on the reported Calpha coordinates of the protein and results of a structure-activity relationship study using four structurally distinct classes of inhibitors, recombinant human AR, and four single-site-directed mutants of this enzyme. The effects of the site-directed mutations on residues within the active site of the enzyme were evaluated by average interaction energy calculations and by calculations of carbon atom surface area changes. These values correlated well with the IC(50) values for zopolrestat with the wild-type and mutant enzymes, validating the model. On the basis of the zopolrestat-binding model, we have proposed binding models for 10 other AR inhibitors. Our models have enabled us to gain a qualitative understanding of the binding domains of the enzyme and how different inhibitors impact the size and shape of the binding site.

Differential gene expression in male and female rat lenses undergoing cataract induction by transforming growth factor-beta (TGF-beta).

Epidemiologic studies in humans as well as immunohistologic studies in animals have demonstrated significant sex differences in the propensity to develop cataract. Several studies suggest that estrogen may play a protective role against cataractogenesis. Indeed, male and ovariectomized female rat lenses have a greater susceptibility to cataract induced by transforming growth factor-beta (TGF-beta) than do normal female lenses. However, in spite of the current evidence that estrogen may play a pivotal role in cataractogenesis, the molecular mechanisms behind this phenomenon are largely undetermined. Our study utilized the differential display procedure to examine gene up- and down-regulation in male, normal female and ovariectomized female rat lenses exposed to TGF-beta. Male and normal female rat lenses were cultured with or without 0.15 ng ml(-1)TGF-beta. Lenses were then harvested, and total RNA was isolated for analysis by reverse-transcriptase differential display. Differentially expressed mRNAs were subcloned, sequenced and identified through GenBank database searches. The original experiment was repeated with the addition of ovariectomized female TGF-beta(+/-) conditions, and all differential patterns of gene expression were verified using Northern blot and RT-PCR analysis. Screening of approximately 12% of the mRNA population led to the identification of 27 differentially expressed cDNAs. Notably, strong gender differences were found in expression levels of gammaB-crystallin. In addition, proteasome Z subunit was up-regulated in TGF-beta-treated male and ovariectomized female lenses, but was down-regulated in TGF-beta-treated normal female lenses. This pattern of expression is consistent with the increased susceptibility of male and ovariectomized lenses to TGF-beta-induced cataract. We conclude that differential display is a useful and expedient method for analysing changes in gene expression in the lens. Structural and functional studies of the genes identified in this study may further elucidate mechanisms underlying the TGF-beta-induced cataract formation and differential rates of cataractogenesis in males vs females. In particular, our data suggest that the role of proteasome Z subunit in TGF-beta-induced anterior subcapsular cataract warrants further investigation.

Prion protein expression in mammalian lenses.

PURPOSE: Aging and oxidative stress resulting from over-expression of Alzheimer precursor protein (betaAPP) have been studied as important factors contributing to the major age-related (sporadic), and minor (hereditary) forms of Alzheimer's disease (AD), and muscle inclusion body myositis, (IBM). AD and prion proteins accumulate in plaques linked with AD and scrapie diseases, and in rimmed vacuoles of IBM. Soluble beta-amyloid (Abeta) fibrillar forms are now thought to play a critical role in and outside of cells by producing oxidative stress. In lens, betaAPP and Abeta increase in cultured lenses exposed to oxidative stress, and in areas of lens fiber cell degeneration in thiamine (vitamin B1) deprived mice, a classic model of systemic oxidative stress. The purpose of the present study is to extend our studies of amyloid disease-related protein expression in mammalian lenses. METHODS: Western blot, immunohistochemical detection, and RT-PCR methods were used to identify and quantitate prion protein expression in human, monkey, and guinea pig lenses. RESULTS: We demonstrate for the first time that prion protein gene expression increases with oxidative stress in cultured human lens epithelial cells. In addition, we detected greater prion protein gene expression in fiber cells than epithelial cells in vivo. This is consistent with increases in prion protein expression demonstrated in myoblasts and neuronal cells induced to differentiate. Our initial investigations of prion protein in human lens cataracts identified increased prion protein immunoreactivity in regions of lens fiber cell degeneration. CONCLUSIONS: The present data indicate that prion protein expression increases during lens development, and is substantially increased in cultured human lens epithelial cells exposed to oxidative stress. We also provide evidence that prion protein immunoreactivity can be increased in regions of fiber cell disorganization. These data suggest a potential role for prion protein as a marker for some types of lens pathology, and in the mechanism of oxidative stress-related lens degeneration.

Aldose and aldehyde reductases: structure-function studies on the coenzyme and inhibitor-binding sites.

PURPOSE: To identify the structural features responsible for the differences in coenzyme and inhibitor specificities of aldose and aldehyde reductases. METHODS: The crystal structure of porcine aldehyde reductase in complex with NADPH and the aldose reductase inhibitor sorbinil was determined. The contribution of each amino acid lining the coenzyme-binding site to the binding of NADPH was calculated using the Discover package. In human aldose reductase, the role of the non-conserved Pro 216 (Ser in aldehyde reductase) in the binding of coenzyme was examined by site-directed mutagenesis. RESULTS: Sorbinil binds to the active site of aldehyde reductase and is hydrogen-bonded to Trp 22, Tyr 50, His 113, and the non-conserved Arg 312. Unlike tolrestat, the binding of sorbinil does not induce a change in the side chain conformation of Arg 312. Mutation of Pro 216 to Ser in aldose reductase makes the binding of coenzyme more similar to that of aldehyde reductase. CONCLUSIONS: The participation of non-conserved active site residues in the binding of inhibitors and the differences in the structural changes required for the binding to occur are responsible for the differences in the potency of inhibition of aldose and aldehyde reductases. We report that the non-conserved Pro 216 in aldose reductase contributes to the tight binding of NADPH.

Na+, K+-ATPase inhibitors down-regulate gene expression of the intracellular signaling protein 14-3-3 in rat lens.

To identify genes that are differentially expressed by Na+, K+-ATPase inhibitors, we used the differential display technique to compare mRNA expression patterns in rat lens. Lenses were treated with 10 microM ouabain, bufalin, or 19-norbufalin derivative for 24 h and were compared with control lenses. Differential display analysis revealed that one of the down-regulated genes was 14-3-3 theta. Down-regulation was confirmed by Northern blot and by reverse transcription-polymerase chain reaction analysis. Reverse transcription-polymerase chain reaction of additional 14-3-3 isoforms revealed that the eta and gamma isoforms of 14-3-3 are also down-regulated by ouabain, bufalin, and 19-norbufalin derivative, whereas the zeta isoform is down-regulated only by bufalin. Down-regulation of the 14-3-3 isoforms occurred without a significant change in gamma-crystallin gene expression. These results demonstrate that one of the consequences of Na+, K+-ATPase inhibition by exogenous or endogenous inhibitors is the down-regulation of mRNA transcripts encoding several isoforms of 14-3-3. Because the 14-3-3 proteins are multifunctional regulatory proteins, the reduction in the abundance of various isoforms will have profound effects on cell function.

Oxidative stress induces differential gene expression in a human lens epithelial cell line.

PURPOSE: To identify differentially expressed genes in a human lens epithelial cell line exposed to oxidative stress. METHODS: Reverse transcriptase-polymerase chain reaction (RT-PCR) differential display was used to evaluate differential gene expression in a human lens epithelial cell line (SRA 01-04) when cells were exposed for 3 hours to a single bolus of 200 microM hydrogen peroxide. Differentially expressed genes were identified through DNA sequencing and a nucleotide database search. Differential expression was confirmed by northern blot and RT-PCR analyses. RESULTS: Using 18 primer sets, 28 RT-PCR products were differentially expressed between control and hydrogen peroxide-treated cells. In stressed cells, mitochondrial transcripts nicotinamide adenine dinucleotide (NADH) dehydrogenase subunit 4 and cytochrome b were downregulated 4-fold. Of the cytoplasmic mRNAs, glutamine cyclotransferase decreased 10-fold, whereas cytokine-inducible nuclear protein, alternative splicing factor 2, and beta-hydroxyisobutyryl-coenzyme A hydrolase increased 2-, 4-, and 10-fold, respectively. Analysis of mitochondrial transcripts in a 24-hour time course showed that NADH dehydrogenase subunit 4 mRNA decreased by 2-fold as early as 1 hour after oxidative stress, whereas the rate of decrease was slower for cytochrome b, cytochrome oxidase III, and 16S rRNA. CONCLUSIONS: Oxidative stress induced specific expressed gene changes in hydrogen peroxide-treated lens cells, including genes involved in cellular respiration and mRNA and peptide processing. These early changes may reflect pathways involved in the defense, pathology, or both of the lens epithelium, which is exposed to oxidative stress throughout life.

Probing the inhibitor-binding site of aldose reductase with site-directed mutagenesis.

Aldose reductase (AR) has been implicated in the etiology of the secondary complications of diabetes, and enzyme inhibitors have been proposed as therapeutic agents. While effectively preventing the development of diabetic complications in animals, results from clinical studies of AR inhibitors have been disappointing, possibly due to poor potency in man. To assist in the design of more potent and specific inhibitors, crystallographic studies have attempted to identify enzyme-inhibitor interactions. Resolution of crystal complexes has suggested that the inhibitors bind to the enzyme active site and are held in place through hydrogen bonding and van der Waals interactions formed within two hydrophobic pockets. To confirm and extend these findings we quantified inhibitor activity with single, site-directed, mutant, human AR enzymes in which the apolar active-site residues tryptophan 20, -79, -111 and phenylalanine 115 were replaced with alanine or tyrosine, decreasing the potential for van der Waals interactions. Consistent with molecular models, the inhibitory activity of Tolrestat, Sorbinil and Zopolrestat decreased 800-2000-fold when tested with the mutant enzyme in which Trp20 was replaced with alanine. Further, alanine substitution for Trp111 decreased Zopolrestat's activity 400-fold, while mutations to Trp79 and Phe115 had little effect on the activity of any of the inhibitors. The alanine mutation at Trp111 had no effect on Tolrestat's activity but decreased the activity of Sorbinil by about 1000-fold. These latter effects were unanticipated based on the number of non-bonded interactions between the inhibitors, Tolrestat and Sorbinil, and Trp20 and Trp111 that have been identified in the crystal structures. In spite of these unexpected findings, our results are consistent with the hypothesis that AR inhibitors occupy the enzyme active site and that hydrophobic interactions between the enzyme and inhibitor contribute to inhibitor binding stability.

Characterization of the mouse aldose reductase gene and promoter in a lens epithelial cell line.

PURPOSE: To clone and characterize the mouse aldose reductase (AR) gene and evaluate the functional promoter under basal and hypertonic conditions in mouse lens epithelial cells. METHODS: The mouse AR gene structure was determined by DNA sequencing, and its chromosomal localization was determined by fluorescent in situ hybridization. A luciferase reporter gene was utilized to assess promoter activities of mouse, rat, and human AR deletion constructs as well as mouse site-directed mutants containing specific deletions of an aldose reductase enhancer element (AEE) or a tonicity response element (TonE). Electrophoretic mobility shift assays were performed to evaluate binding of trans-acting factors to mouse AEE and TonE. RESULTS: The mouse AR gene (14.2 Kb) is located on chromosome 6. The basal AR promoter activity was greatest for the rat followed by mouse and human. All 3 species demonstrated increased promoter activity under hypertonic conditions. Deletion of TonE decreased mouse AR basal activity 2.5-fold and substantially reduced the osmotic response. Deletion of AEE had only a slight effect on AR promoter activity. Nevertheless, AEE strongly bound multiple trans-acting factors under nonstressed and stressed conditions, while weaker binding was evident for TonE. CONCLUSIONS: Species-specific differences in AR promoter activities suggest the presence of unique regulatory cis-acting elements. The effects of AEE or TonE on AR transcription appear to involve complex transcriptional regulatory mechanisms.

Studies on the inhibitor-binding site of porcine aldehyde reductase: crystal structure of the holoenzyme-inhibitor ternary complex.

Aldehyde reductase is an enzyme capable of metabolizing a wide variety of aldehydes to their corresponding alcohols. The tertiary structures of aldehyde reductase and aldose reductase are similar and consist of an alpha/beta-barrel with the active site located at the carboxy terminus of the strands of the barrel. We have determined the X-ray crystal structure of porcine aldehyde reductase holoenzyme in complex with an aldose reductase inhibitor, tolrestat, at 2.4 A resolution to obtain a picture of the binding conformation of inhibitors to aldehyde reductase. Tolrestat binds in the active site pocket of aldehyde reductase and interacts through van der Waals contacts with Arg 312 and Asp 313. The carboxylate group of tolrestat is within hydrogen bonding distance with His 113 and Trp 114. Mutation of Arg 312 to alanine in porcine aldehyde reductase alters the potency of inhibition of the enzyme by aldose reductase inhibitors. Our results indicate that the structure of the inhibitor-binding site of aldehyde reductase differs from that of aldose reductase due to the participation of nonconserved residues in its formation. A major difference is the participation of Arg 312 and Asp 313 in lining the inhibitor-binding site in aldehyde reductase but not in aldose reductase.

Na,K-ATPase response to osmotic stress in primary dog lens epithelial cells.

PURPOSE: Na,K-ATPase activity increases in lens cells exposed to hypertonic stress. To test whether the increase in activity involves stimulation of Na,K-ATPase expression, dog lens epithelial cells were subjected to hypertonic stress, and the time course of Na,K-ATPase protein and mRNA response was measured. METHODS: Primary cultures of dog lens epithelial cells were maintained in isotonic or hypertonic media over the course of several days. Rubidium-86 uptake measurements, immunoreactive protein, and northern blot analysis were performed. RESULTS: Dog lens epithelial cells exposed to hypertonic stress from culture medium supplemented with 150 mM NaCl or 250 mM cellobiose showed a twofold increase in Na,K-ATPase activity. The increase in activity was blocked by cycloheximide and was reversible when the cells were returned to isotonic medium. This activity was unaffected by the aldose reductase inhibitor, tolrestat. Na,K-ATPase protein and mRNA levels increased in cells exposed to medium containing 150 mM NaCl. Northern blot analysis showed that the alpha-1 and beta-1 mRNA levels increased as early as 6 hours and maximally increased 1.5-fold to twofold by 12 to 24 hours. CONCLUSIONS: Elevation of Na,K-ATPase activity in dog lens epithelial cells exposed to hypertonic stress was associated with increased expression of Na,K-ATPase subunit mRNAs and was dependent on protein synthesis. These results suggest that upregulation of the enzyme activity is the result of an induction of Na,K-ATPase.

Residues affecting the catalysis and inhibition of rat lens aldose reductase.

Aldose reductase (AR), the first enzyme of the polyol pathway, has been implicated in diabetic complications. Results of recent clinical studies have shown that compounds that inhibit aldose reductase (ARIs) and block the flux of glucose through the polyol pathway have provided benefit to diabetic neuropathic patients. Since many ARIs show broad substrate specificity, emphasis on the structure-function properties of the AR enzyme will help in the refinement and design of future inhibitors. To this end, catalysis and inhibition of rat lens aldose reductase was examined following site-directed mutagenesis. Replacement of tyrosine 48 with phenylalanine (Y48F) resulted in an enzyme form with less than 0.25% activity with DL-glyceraldehyde and no detectable activity with p-nitrobenzaldehyde or xylose, although circular dichroism spectra and NADPH binding affinity were similar to wild-type AR. Mutation of histidine 110 to glutamine (H110Q) also resulted in a less active protein with an approximate 3-fold decrease in kcat for the reduction of DL-glyceraldehyde; slight or no activity was measured with other substrates and an increase of 195-fold over wild type was observed in the Km for glyceraldehyde. H110Q was less sensitive to inhibition by aldose reductase inhibitors. The most dramatic change was seen with imeristat, which showed an 1800-fold increase in IC50. Mutation of cysteine 298 to serine (C298S) affected enzyme function by increasing kcat 2- to 4-fold and increasing Km 15- to 48-fold, with DL-glyceraldehyde, p-nitrobenzaldehyde or xylose as substrates. As a result kcat/Km, catalytic efficiency, dropped to approx. 10% of control. Inhibition of C298S was not noticeably different from wild type. Substitution of histidine 187 or 200 with glutamine (H187Q, H200Q) had little effect on AR catalysis or inhibition. Based on structural and mutagenesis studies of human AR and the conservation of amino acids between human and rat, these data would indicate that Y48, H110, and C298 are important residues in the active site of rat AR and that Y48 is most likely the proton donor during substrate reduction by rat lens aldose reductase. In addition, these studies indicate that mutagenesis of H110 also affects aldose reductase inhibition.

In vitro expression of rat lens aldose reductase in Escherichia coli.

Aldose reductase (alditol:NADP+ oxidoreductase, EC 1.1.1.21), an enzyme that converts glucose to sorbitol, the first step of the polyol pathway, has been implicated in secondary complications of diabetes, such as cataracts, retinopathy, neuropathy, and nephropathy. Aldose reductase inhibitors have been observed to prevent or delay the onset of these complications; however, more potent and specific inhibitors are needed. Development of new inhibitors necessitates a better understanding of the molecular structure of this protein. To elucidate the structure-function relationships of aldose reductase and to develop methods of regulating this enzyme, large and homogeneous quantities of rat lens aldose reductase have been expressed in bacterial cells. A construction of the complete coding sequence and 3' untranslated region for rat lens aldose reductase was assembled in the expression vector pKK233-2 (Pharmacia). This construction expresses an active enzyme that has been purified and demonstrates kinetic, immunological, and inhibitory properties similar to rat lens aldose reductase.

A superfamily of NADPH-dependent reductases in eukaryotes and prokaryotes.

Aldose reductase (AR) is implicated in some of the disabling complications of diabetes, including neuropathy, retinopathy and cataracts. Our studies are aimed at further clarifying the role of AR in diabetes and facilitating the design of new classes of potent, specific AR inhibitors by gaining an understanding of the protein structure of AR. To this end, we have determined the complete protein sequence of rat lens AR using cDNA analysis and primer extension of mRNA. By comparing protein sequences, we have found that the structural relatedness (41% to 57%) among the vertebrate proteins, aldose reductase, aldehyde reductase, prostaglandin F synthase and the frog lens protein rho-crystallin can now be extended to prokaryotes by the inclusion of Corynebacterium 2,5-diketo-D-gluconate reductase. This more distantly related protein shares 30-40% identity with the vertebrate enzymes. Sequence alignments reveal that 18% of the amino acids are completely conserved in all members of the superfamily, many of them in clusters, suggesting that they mark important structural features such as the nucleotide binding site and substrate binding site. rho-Crystallin, which is structurally related to this superfamily of NADPH-dependent reductases, does not appear to reduce PGH2, PGD2, xylose or glyceraldehyde to any appreciable extent. It does, however, bind NADPH.

Alteration of a developmentally regulated, heat-stable polypeptide in the lens of the Philly mouse. Implications for cataract formation.

The beta-crystallin basic principal polypeptide (beta Bp) appears to be altered in the lens of the Philly mouse and may be the main defect in this hereditary cataract. Northern blot analysis showed that an mRNA encoding for beta Bp is present in the Philly mouse lens, but normal beta Bp could not be detected. Instead, a different protein related to beta Bp has been observed. Western blot analysis with antibodies against specific beta Bp peptide sequences showed that the Philly protein shares the same amino-terminal residue as beta Bp but lacks a part of the carboxyl-terminal half of normal beta Bp. The altered protein is slightly smaller than beta Bp and has a more acidic isoelectric point by two-dimensional gel electrophoresis. It also lacks the property of heat stability characteristic of normal beta Bp. The mapping of the alteration in beta Bp may give insight into the nature of the heat stability of this protein as well as some indication of the structural components that are necessary to maintain optical clarity in the lens.

The comparison of human lens crystallins using three monoclonal antibodies.

Three monoclonal antibodies against lens crystallin have been used to study the accumulation of specific polypeptides during development of the human lens. One antibody which recognizes an antigen common to three polypeptides with molecular weights close to 31,000 reacted equally well to the human lens cortex and nucleus and had a similar binding activity to proteins isolated from embryonic and older human lenses. This suggests that the antigen accumulates to the same degree in human lenses during development. The second monoclonal antibody to the 24,000 molecular weight gamma-crystallin showed increased binding at the older ages indicating the increased accumulation of this protein during lens development. The third monoclonal antibody to a beta-crystallin of 27,000 molecular weight showed little if any reactivity at the embryonic age and revealed a clear difference between the binding with cortical and nuclear protein at older ages. It appears that the 27,000 molecular weight beta-crystallin may not be synthesized in the embryonic human lens.

Synthesis of gamma crystallin by a cloned cell line from Nakano mouse lens.

A cloned cell line was derived from a culture of Nakano mouse lens epithelial cells. The cloned cells grew vigorously and produced large numbers of lentoid bodies. Sodium dodecyl sulfate (SDS) and non-SDS slab-gel electrophoresis of the soluble proteins from the cultured cell revealed protein bands identical in pattern to those of purified gamma crystallin. Antibody to mouse gamma crystallin reacted to the soluble protein fraction of the cultured cells, indicating the synthesis in culture of gamma crystallin by this cloned cell line.