Physiological functions and hormonal regulation of mouse vas deferens protein (AKR1B7) in steroidogenic tissues

The MVDP (mouse vas deferens protein) gene encodes an aldose reductase-like protein (AKR1B7) highly expressed in vas deferens epithelium and zona fasciculata of the adrenal cortex. Recombinant MVDP showed kinetic properties distinct from those of aldose reductase, including its spectrum of substrates, cofactor preference and sensitivity to inhibitors. We demonstrate that in adrenocortical cells, MVDP, rather than aldose reductase, is the principal reductase for isocaproaldehyde (a product of side-chain cleavage of cholesterol) and 4-hydroxynonenal (a lipid peroxidation product). In steroidogenic tissues MVDP expression is regulated by pituitary trophic hormones, namely ACTH in adrenals, FSH in ovaries, and LH in testicular Leydig cells.     

Physiological functions and hormonal regulation of mouse vas deferens protein (AKR1B7) in steroidogenic tissues

The MVDP (mouse vas deferens protein) gene encodes an aldose reductase-like protein (AKR1B7) highly expressed in vas deferens epithelium and zona fasciculata of the adrenal cortex. Recombinant MVDP showed kinetic properties distinct from those of aldose reductase, including its spectrum of substrates, cofactor preference and sensitivity to inhibitors. We demonstrate that in adrenocortical cells, MVDP, rather than aldose reductase, is the principal reductase for isocaproaldehyde (a product of side-chain cleavage of cholesterol) and 4-hydroxynonenal (a lipid peroxidation product). In steroidogenic tissues MVDP expression is regulated by pituitary trophic hormones, namely ACTH in adrenals, FSH in ovaries, and LH in testicular Leydig cells.     

Osmotic regulation of aldose reductase protein synthesis in renal medullary cells

Renal medullary cells are normally exposed to high extracellular NaCl as part of the urinary concentrating mechanism. They react to this stress by accumulating sorbitol and other organic osmolytes. PAP-HT25, a line of epithelial cells derived from rabbit renal inner medulla, expresses this response. In hypertonic medium, these cells accumulate large amounts of sorbitol. There is a large increase in the amount of aldose reductase, which catalyzes production of sorbitol from glucose. The purpose of the present study was to investigate whether the aldose reductase protein increases because of faster synthesis or slower degradation. We measured the rate of synthesis and degradation of aldose reductase protein by pulse-chase with [35S]methionine, followed by immunoprecipitation with specific antiserum and autoradiography. The protein synthesis rate was 6 times greater in cells grown in hypertonic (500 mosmol/kg) medium, than in those grown in normal (300 mosmol/kg) medium. When control cells were switched to hypertonic medium, the synthesis rate increased 15-fold by 24 h, then decreased to 11-fold after 48 h. In contrast, synthesis rate continued to increase past 24 h when accumulation of sorbitol was prevented by inhibiting aldose reductase activity with Tolrestat. Thus, there is a feedback mechanism by which cellular sorbitol accumulation inhibits aldose reductase protein synthesis. Degradation of aldose reductase protein was slow (only about 25% in 3 days) and was not affected by osmolality. Thus, the osmoregulatory increase in aldose reductase protein is due to an increase in its synthesis rate and not to any change in its degradation.     

Characterization and purification of a mammalian osmoregulatory protein, aldose reductase, induced in renal medullary cells by high extracellular NaCl

GRB-PAP1 is a continuous line of epithelial cells derived from a rabbit renal inner medulla. Elevation of the NaCl concentration in the medium bathing these cells strongly induced the expression of a soluble protein with an apparent molecular mass of 39 kDa. The protein, purified by affinity chromatography with Amicon Matrex Gel Orange A, had enzyme activity characteristic of aldose reductase (alditol:NADPH+ oxidoreductase, EC 1.1.1.21). Goat antiserum against this purified aldose reductase selected the 39-kDa band from immunoblots of cells grown in a medium containing high NaCl. When the osmolality of the medium was increased by adding NaCl, the amount of aldose reductase protein and the aldose reductase activity increased together from very low to sustained high levels over several days. The aldose reductase protein was more than 10% of the soluble cell protein when cells were propagated in medium made hyperosmotic by adding NaCl to increase medium osmolality to 600 mosm.kg-1.     

Identification of a novel aldose reductase-like gene upregulated in the failing heart of cardiomyopathic hamster

Cardiomyopathy (CM) is degenerative disease of myocardium which leads to severe cardiac failure. Although many causative genes for CM have been identified, molecular pathogenesis of CM is not fully understood. In this study, we searched for a novel pathway recruited in the development of CM by using BIO14.6 hamster as an animal model for human CM. We screened upregulated genes in the left ventricle by differential display technique and searched for a gene which had never been linked to CM. We identified a novel gene overexpressed in BIO14.6 hamster ventricles, which was considered to be a new member of aldo-keto reductase (AKR) superfamily. The cloned cDNA encoded a 316 amino acid polypeptide with calculated molecular mass of 35,804, which showed high amino acid sequence similarities to aldose reductase and its relative: 69.6% to AKR1B1 (human aldose reductase), 68.4% to AKR1B3 (mouse aldose reductase), and 85.8% to AKR1B7 (mouse vas deferens protein). The upregulation of this aldose reductase-like gene in BIO14.6 hamster ventricles (6.3 ± 0.8-fold) seemed to be influenced by the overexpression of activator protein-1 present there. With the fact that AKR1B1, AKR1B3, and AKR1B7 have synthetic activities of prostaglandin F2α, the aldose reductase-like protein could cause cardiac hypertrophy through production of prostaglandin F2α whose precursor and receptor were abundant in BIO14.6 hamster ventricles. Aldose reductase and its related proteins would give a new clue to dissect the pathogenesis of CM including oxidative stress and cardiac hypertrophy, and to develop a new drug for the treatment of CM.     

Crystal structure of CHO reductase, a member of the aldo-keto reductase superfamily

Chinese hamster ovary (CHO) reductase is an enzyme belonging to the aldo-keto reductase (AKR) superfamily that is induced by the aldehyde-containing protease inhibitor ALLN (Inoue, Sharma, Schimke, et al., J Biol Chem 1993;268: 5894). It shows 70% sequence identity to human aldose reductase (Hyndman, Takenoshita, Vera, et al., J Biol Chem 1997;272:13286), which is a target for drug design because of its implication in diabetic complications. We have determined the crystal structure of CHO reductase complexed with nicotinamide adenine dinucleotide phosphate (NADP)+ to 2.4 A resolution. Similar to aldose reductase and other AKRs, CHO reductase is an alpha/beta TIM barrel enzyme with cofactor bound in an extended conformation. All key residues involved in cofactor binding are conserved with respect to other AKR members. CHO reductase shows a high degree of sequence identity (91%) with another AKR member, FR-1 (mouse fibroblast growth factor-regulated protein), especially around the variable C-terminal end of the protein and has a similar substrate binding pocket that is larger than that of aldose reductase. However, there are distinct differences that can account for differences in substrate specificity. Trp111, which lies horizontal to the substrate pocket in all other AKR members is perpendicular in CHO reductase and is accompanied by movement of Leu300. This coupled with movement of loops A, B, and C away from the active site region accounts for the ability of CHO reductase to bind larger substrates. The position of Trp219 is significantly altered with respect to aldose reductase and appears to release Cys298 from steric constraints. These studies show that AKRs such as CHO reductase are excellent models for examining the effects of subtle changes in amino acid sequence and alignment on binding and catalysis.     

Localization, isolation and properties of three NADPH-dependent aldehyde reducing enzymes from dog kidney

Three kinds of NADPH-dependent aldehyde reducing enzymes were present in the dog kidney. Aldose reductase was located in the inner medulla region and aldehyde reductase in all regions of the renal cortex, outer medulla and inner medulla. In addition, a new reductase designated tentatively as high-Km aldose reductase, which was converted into an aldose reductase-like enzyme, was present in the inner medulla region of the kidney. Aldose reductase, aldehyde reductase and high-Km aldose reductase were purified to homogeneity from each region of the dog kidney. The molecular weight of aldose reductase was estimated to be 38,500 by SDS-polyacrylamide gel electrophoresis and the isoelectric point was found to be 5.7 by chromatofocusing. Aldose reductase had activity for aldo-sugars such as D-xylose, D-glucose and D-galactose as substrates and utilized both NADPH and NADH as coenzymes. Sulfate ions resulted in over 2-fold activation of aldose reductase. All aldehyde reductases from the three regions had the same properties. The molecular weights and isoelectric points of aldehyde reductases were 40,000 and 6.1, respectively. The aldehyde reductases were inactive for D-hexose, utilized only NADPH as coenzyme and were not affected by sulfate ions. High-Km aldose reductase had a molecular weight of 38,500 and an isoelectric point of 5.4. It had activity for aldo-sugars, but showed much higher Km and lower kcat/Km values than aldose reductase. Sulfate ions inhibited high-Km aldose reductase. It was converted into an aldose reductase-like enzyme by incubation in phosphate buffer at pH 7.0. The three kinds of enzymes were strongly inhibited by the known aldose reductase inhibitors. However, aldehyde reductase and high-Km aldose reductase were, in general, less susceptible than aldose reductase.     

Purification and characterization of human testis aldose and aldehyde reductase

1. Aldose reductase and aldehyde reductase were purified to homogeneity from human testis. 2. The molecular weight of aldose reductase and aldehyde reductase were estimated to be 36,000 and 38,000 by SDS-PAGE, and the pI values of these enzymes were found to be 5.9 and 5.1 by chromatofocusing, respectively. 3. Aldose reductase had activity for aldo-sugars, whereas aldehyde reductase was virtually inactive for aldo-sugars. The Km values of aldose reductase for D-glucose, D-galactose and D-xylose were 57, 49 and 6.2 mM, respectively. Aldose reductase utilized both NADPH and NADH as coenzymes, whereas aldehyde reductase only NADPH. 4. Sulfate ion caused 3-fold activation of aldose reductase, but little for that of aldehyde reductase. 5. Sodium valproate inhibited significantly aldehyde reductase, but not aldose reductase. Aldose reductase was inhibited strongly by aldose reductase inhibitors being in clinical trials at concentrations of the order of 10(-7)-10(-9) M. Aldehyde reductase was also inhibited by these inhibitors, but its susceptibility was less than aldose reductase. 6. Reaction of aldose reductase with pyridoxal 5'-phosphate (PLP) resulted ca 2.5-fold activation, but aldehyde reductase did not cause the activation. PLP-treated aldose reductase has lost the susceptibility to aldose reductase inhibitor.     

Purified rat lens aldose reductase. Polyol production in vitro and its inhibition by aldose reductase inhibitors.

The production of polyols in vitro by highly purified aldose reductase (EC 1.1.1.21) was monitored by g.l.c. In the presence of NADPH aldose reductase reduced glucose, galactose and xylose to the respective polyols sorbitol, galactitol and xylitol. The rates of formation of these polyols closely mirrored the Km values for the substrates obtained from kinetic measurements that monitored the rate of disappearance of NADPH. No polyol production occurred in the absence of purified aldose of purified aldose reductase, and analysis by g.l.c. revealed only the presence of unchanged monosaccharides. Addition of the aldose reductase inhibitor sorbinil to purified rat lens aldose reductase incubated with xylose in the presence of NADPH resulted in decreased xylitol production. However, aldose reductase inhibitors produced no effect in altering the rate of Nitro Blue Tetrazolium formation from either glucose or xylose, indicating that the observed inhibition in vitro does not result from a free-radical-scavenger effect.     

Induction of the enzyme aldose reductase in a lens epithelial cell line from a transgenic mouse

A lens epithelial cell line established from a transgenic mouse synthesizes high levels of the enzyme aldose reductase which converts sugars to polyols. This enzyme has been implicated in the formation of sugar cataracts in animals and with diabetic complications in man. The mouse aldose reductase has been characterized and by sodium dodecyl sulfate-polyacrylamide gel electrophoresis has an apparent molecular mass of 38,000, similar to the enzyme in rat and man. The cellular enzyme is inhibited by two aldose reductase inhibitors: Sorbinil (IC50 = 1.8 X 10(-7) M) and Alcon 1576 (IC50 = 7.8 X 10(-8) M). The amount and the specific activity of the aldose reductase can be further increased in the cells by raising the osmolarity of the medium to 500 mOSM. Although the amount of aldose reductase is increased approximately sevenfold under these conditions, alpha-crystallin, one of the main lens specific proteins, remained at about the same concentration. No detectable increase in sorbitol was found within the cells, in contrast to published reports on renal cells in which this polyol increases under similar hyperosmotic conditions; however, in the lens cells there was a five-fold increase in the inositol content, suggesting that this polyol rather than sorbitol may be used to compensate for some of the changes in the osmolarity. The induction of the enzyme aldose reductase without the apparent accumulation of its product suggests a complex mechanism for osmoregulation in the lens cells.     

An ABA and GA modulated gene expressed in the barley embryo encodes an aldose reductase related protein.

In most higher plants a period of desiccation is the terminal event in embryogenesis. Excised barley embryos acquire desiccation tolerance at a precise developmental stage and cDNA clones have been isolated which are temporally linked with desiccation tolerance. One such clone (pG22-69) with a putative gene product of 34 kd displays high structural homology to mammalian genes encoding an NADPH dependent aldose reductase involved in the synthesis of sorbitol. This first aldose reductase gene of plants is expressed constitutively during embryo maturation and is modulated by the plant hormones abscisic acid (ABA) and gibberellic acid (GA). Immunohistochemistry showed that the protein is preferentially expressed in tissues formed at early stages in embryogenesis. Measurements of enzymatic activity indicate that pG22-69 encodes an active aldose reductase. The finding of this reductase activity and the cloning of the corresponding gene supports the existence of a metabolic pathway in plants playing a role in the synthesis of osmolytes like sorbitol. The significance of this work is that genes of related structure and functions are being used in diverse organisms to fulfil stress related biological requirements.     

Aldose reductase and p-crystallin belong to the same protein superfamily as aldehyde reductase

Aldose reductase (EC 1.1.1.21) has been implicated in a variety of diabetic complications. Here we present the first primary sequence data for the rat lens enzyme, obtained by amino acid and cDNA analysis. We have found structural similarities with another NADPH-dependent oxidoreductase: human liver aldehyde reductase (EC 1.1.1.2). The identity between these two enzymes is 50%. Both enzymes share approx. 40-50% homology with p-crystallin, a major lens protein present only in the frog, Rana pipiens. We propose that aldose reductase, aldehyde reductase and p-crystallin are members of a superfamily of related proteins.     

Molecular cloning of cDNA coding for kidney aldose reductase. Regulation of specific mRNA accumulation by NaCl-mediated osmotic stress

Cells generally respond to long-term hyperosmotic stress by accumulating nonperturbing organic osmolytes. Unlike bacteria, in which molecular mechanisms involved in the increased accumulation of osmolytes have been identified, those in multicellular organisms are virtually unknown. In mammals, during antidiuresis, cells of the renal inner medulla are exposed to high and variable extracellular NaCl. Under these conditions, the cells contain a high level of sorbitol and other osmolytes which help balance the high extracellular osmolality. PAP-HT25 is a continuous line of cells derived from rabbit renal inner medulla. When medium osmolality is increased by raising the NaCl concentration, these cells accumulate sorbitol. The sorbitol is synthesized from glucose in a reaction catalyzed by aldose reductase. When the medium is made hyperosmotic, aldose reductase activity increases because of a larger increase in the amount of enzyme. This increase is produced by the accelerated rate of synthesis of aldose reductase protein. The purpose of the present studies was to examine the mechanism of this increase in aldose reductase protein by measuring the relative abundance of aldose reductase mRNA. A cDNA clone coding for rabbit kidney aldose reductase was isolated. Antisense RNA probes transcribed from this clone hybridized specifically with a 1.5-1.6 kilobase mRNA in Northern blots. Cells grown chronically in hyperosmotic medium had a relative abundance of this specific mRNA which was six times that of cells grown in isoosmotic medium. When cells grown in isoosmotic medium were switched to hyperosmotic medium, the level of aldose reductase mRNA peaked (18-fold) at 18-24 h. The induction of aldose reductase mRNA by osmotic stress was reversible. Our finding of increased abundance of a specific mRNA in direct response to hyperosmotic stress represents the first report of such an effect in animals.     

Cloning and expression of human aldose reductase

The complete amino acid sequence of human retina and muscle aldose reductase was determined by nucleotide analysis of cDNA clones isolated using synthetic oligonucleotide probes based on partial amino acid sequences of purified human psoas muscle aldose reductase. The cDNA sequence differs substantially in the noncoding and coding regions of recently published sequences of this enzyme. The mRNA for aldose reductase was abundantly expressed in HeLa cells, but only scarcely in a neuroblastoma cell line. Recombinant baculovirus containing one of the muscle cDNA clones was constructed and used to infect Spodoptera frugiperda (SF9) cells. A prominent protein with an apparent molecular size of 36 kDa was identified by sodium dodecyl sulfate-polyacrylamide gel electrophoresis in the culture medium as well as in the homogenate of SF9 cells after 2 days of infection. Culture medium or the supernatant fraction of cell homogenates containing this protein had high aldose reductase activity which showed characteristics of the reported human enzyme. These findings indicate that the amino acid sequence reported in this paper represents human retina and muscle aldose reductase and that functional human aldose reductase can be expressed in large amounts in a baculovirus expression system. The result should facilitate refined structural analysis and the development of new specific aldose reductase inhibitors for the treatment of diabetic complications.     

Aldose reductase induced by hyperosmotic stress mediates cardiomyocyte apoptosis: differential effects of sorbitol and mannitol

Cells adapt to hyperosmotic conditions by several mechanisms, including accumulation of sorbitol via induction of the polyol pathway. Failure to adapt to osmotic stress can result in apoptotic cell death. In the present study, we assessed the role of aldose reductase, the key enzyme of the polyol pathway, in cardiac myocyte apoptosis. Hyperosmotic stress, elicited by exposure of cultured rat cardiac myocytes to the nonpermeant solutes sorbitol and mannitol, caused identical cell shrinkage and adaptive hexose uptake stimulation. In contrast, only sorbitol induced the polyol pathway and triggered stress pathways as well as apoptosis-related signaling events. Sorbitol resulted in activation of the extracellular signal-regulated kinase (ERK), p54 c-Jun N-terminal kinase (JNK), and protein kinase B. Furthermore, sorbitol treatment resulting in induction and activation of aldose reductase, decreased expression of the antiapoptotic protein Bcl-xL, increased DNA fragmentation, and glutathione depletion. Apoptosis was attenuated by aldose reductase inhibition with zopolrestat and also by glutathione replenishment with N-acetylcysteine. In conclusion, our data show that hypertonic shrinkage of cardiac myocytes alone is not sufficient to induce cardiac myocyte apoptosis. Hyperosmolarity-induced cell death is sensitive to the nature of the osmolyte and requires induction of aldose reductase as well as a decrease in intracellular glutathione levels.     

Aldose reductase from human psoas muscle. Purification, substrate specificity, immunological characterization, and effect of drugs and inhibitors

Aldose reductase (ALR2) has been purified to homogeneity from human psoas muscle. From sodium dodecyl sulfate-polyacrylamide electrophoresis the enzyme is monomeric and has a molecular weight of 37,000. ALR2 catalyzes the primarily NADPH-dependent reduction of a wide variety of aldehydes, although the enzyme can also utilize NADH. The best substrates for ALR2 are aromatic aldehydes (e.g. pyridine-3-aldehyde; Km = 9 microM; kcat/Km = 150,000 s-1 M-1), while among aldoses DL-glyceraldehyde is the preferred substrate (Km = 72 microM; kcat/Km = 17,250). Low (100 microM) concentrations of CaCl2 and CaSO4 cause a marked inhibition (90%) of ALR2 as do higher concentrations (0.2 M) of MgCl2. (NH4)2SO4 caused a 2-fold activation of ALR2. The enzyme is also inhibited by quercetin and the commercially developed aldose reductase inhibitors alrestatin and sorbinil. ALR2 is inhibited only very slightly by sodium valproate and barbiturates. ALR2 cross-reacts immunologically with human brain and human placental aldose reductase and with ALR2 from monkey tissue. There is no precipitin cross-reaction of ALR2 with aldose reductases from other species nor with human aldehyde reductase 1 (ALR1) or with ALR1 from other species. The data show that human muscle is a new and relatively rich source of a monomeric NADPH/NADH reductase which is clearly identifiable as aldose reductase.     

Molecular cloning and functional expression of a novelNeurospora crassa xylose reductase inSaccharomyces cerevisiae in the development of a xylose fermenting strain

The development of a xylose-fermentingSaccharomyces cerevisiae yeast would be of great benefit to the bioethanol industry. The conversion of xylose to ethanol involves a cascade of enzymatic reactions and processes. Xylose (aldose) reductases catalyse the conversion of xylose to xylitol. The aim of this study was to clone, characterise and express a cDNA copy of a novel aldose reductase (NCAR-X) from the filamentous fungusNeurospora crassa inS. cerevisiae. NCAR-X harbours an open reading frame (ORF) of 900 nucleotides. This ORF encodes a protein (NCAR-X, assigned NCBI protein accession ID: XP_956921) consisting of 300 amino acids, with a predicted molecular weight of 34 kDa. TheNCAR-X-encoded aldose reductase showed significant homology to the xylose reductases ofCandida tenuis andPichia stipitis. WhenNCAR-X was expressed under the control of phosphoglycerate kinase I gene (PGK1) regulatory sequences inS. cerevisiae, its expression resulted in the production of biologically active xylose reductase. Small-scale oxygen-limited xylose fermentation with theNCAR-X containingS. cerevisiae strains resulted in the production of less xylitol and at least 15% more ethanol than the strains transformed with theP. stipitis xylose reductase gene (PsXYL1). TheNCAR-X-encoded enzyme produced byS. cerevisiae was NADPH-dependent and no activity was observed in the presence of NADH. The co-expression of theNCAR-X andPsXYL1 gene constructs inS. cerevisiae constituted an important part of an extensive research program aimed at the development of xylolytic yeast strains capable of producing ethanol from plant biomass.