Characterization of an oligomeric carbonyl reductase of dog liver: its identity with peroxisomal tetrameric carbonyl reductase.

Dog liver contains an oligomeric NADPH-dependent carbonyl reductase (CR) with substrate specificity for alkyl phenyl ketones, but its endogenous substrate and primary structure remain unknown. In this study, we examined the molecular weight and substrate specificity of the enzyme purified from dog liver. The enzyme is a ca. 100-kDa tetramer composing of 27-kDa subunit, and reduces all-trans-retinal and alpha-dicarbonyl compounds including isatin, which are substrates for pig peroxisomal tetrameric carbonyl reductase (PTCR). In addition, the dog enzyme resembles pig PTCR in inhibitor sensitivity to flavonoids, myristic acid, lithocholic acid, bromosulfophthalein and flufenamic acid. Furthermore, the amino acid sequence of dog CR determined by protein sequencing and cDNA cloning was 84% identical to that of pig PTCR and had a C-terminal peroxisomal targeting signal type 1, Ser-His-Leu. The immunoprecipitation using the anti-pig PTCR antibody shows that the dog enzyme is a major form of soluble NADPH-dependent all-trans-retinal reductase in dog liver. Thus, dog oligomeric CR is PTCR, and may play a role in retinoid metabolism as a retinal reductase.

Structure of the tetrameric form of human L-Xylulose reductase: probing the inhibitor-binding site with molecular modeling and site-directed mutagenesis.

L-Xylulose reductase (XR) is a member of the short-chain dehydrogenase/reductase (SDR) superfamily. In this study we report the structure of the biological tetramer of human XR in complex with NADP(+) and a competitive inhibitor solved at 2.3 A resolution. A single subunit of human XR is formed by a centrally positioned, seven-stranded, parallel beta-sheet surrounded on either side by two arrays of three alpha-helices. Two helices located away from the main body of the protein form the variable substrate-binding cleft, while the dinucleotide coenzyme-binding motif is formed by a classical Rossmann fold. The tetrameric structure of XR, which is held together via salt bridges formed by the guanidino group of Arg203 from one monomer and the carboxylate group of the C-terminal residue Cys244 from the neighboring monomer, explains the ability of human XR to prevent the cold inactivation seen in the rodent forms of the enzyme. The orientations of Arg203 and Cys244 are maintained by a network of hydrogen bonds and main-chain interactions of Gln137, Glu238, Phe241, and Trp242. These interactions are similar to those defining the quaternary structure of the closely related carbonyl reductase from mouse lung. Molecular modeling and site-directed mutagenesis identified the active site residues His146 and Trp191 as forming essential contacts with inhibitors of XR. These results could provide a structural basis in the design of potent and specific inhibitors for human XR.

Structural and functional characterization of rabbit and human L-gulonate 3-dehydrogenase.

L-Gulonate 3-dehydrogenase (GDH) catalyzes the NAD(+)-linked dehydrogenation of L-gulonate into dehydro-L-gulonate in the uronate cycle. In this study, we isolated the enzyme and its cDNA from rabbit liver, and found that the cDNA is identical to that for rabbit lens lambda-crystallin except for lacking a codon for Glu(309). The same cDNA species, but not the lambda-crystallin cDNA with the codon for Glu(309), was detected in the lens, which showed the highest GDH activity among rabbit tissues. In addition, recombinant human lambda-crystallin that lacks Glu(309) displays enzymatic properties similar to rabbit GDH. These data indicate that GDH is recruited as lambda-crystallin without gene duplication. An outstanding feature of GDH is modulation of its activity by low concentrations of P(i), which decreases the catalytic efficiency in a dose dependent manner. P(i) also protects the enzyme against both thermal and urea denaturation. Kinetic analysis suggests that P(i) binds to both the free enzyme and its NAD(H)-complex in the sequential ordered mechanism. Furthermore, we examined the roles of Asp(36), Ser(124), His(145), Glu(157 )and Asn(196) in the catalytic function of rabbit GDH by site-directed mutagenesis. The D36R mutation leads to a switch in favor of NADP(H) specificity, suggesting an important role of Asp(36) in the coenzyme specificity. The S124A mutation decreases the catalytic efficiency 500-fold, and the H145Q, N196Q and N195D mutations result in inactive enzyme forms, although the E157Q mutation produces no large kinetic alteration. Thus, Ser(124), His(145) and Asn(196) may be critical for the catalytic function of GDH.

Structure-based discovery of human L-xylulose reductase inhibitors from database screening and molecular docking.

Human L-xylulose reductase (XR) is an enzyme of the glucuronic acid/uronate cycle of glucose metabolism and is a possible target for treatment of the long-term complications of diabetes. In this study we utilised the molecular modelling program DOCK to analyse the 249,071 compounds of the National Cancer Institute Database and retrieved those compounds with high predicted affinity for XR. Several carboxylic acid-based compounds were tested and shown to inhibit XR. These included nicotinic acid (IC50=100 microM), benzoic acid (IC50=29 microM) and their derivatives. These results extend and improve upon the activities of known, commercially available inhibitors of XR such as the aliphatic fatty acid n-butyric acid (IC50=64 microM). To optimise the interaction between the inhibitor and the holoenzyme, the program GRID was used to design de novo compounds based on the inhibitor benzoic acid. The inclusion of a hydroxy-phenyl group and a phosphate to the benzoic acid molecule increased the net binding energy by 1.3- and 2.4-fold, respectively. The resultant compounds may produce inhibitors with improved specificity for XR.

Crystallization and preliminary X-ray diffraction analysis of mouse 3(17)alpha-hydroxysteroid dehydrogenase.

The 3(17)alpha-hydroxysteroid dehydrogenase from mouse is involved in the metabolism of oestrogens, androgens, neurosteroids and xenobiotic compounds. The enzyme was crystallized by the hanging-drop vapour-diffusion method in space group P222(1), with unit-cell parameters a = 84.91, b = 84.90, c = 95.83 A. The Matthews coefficient (VM) and the solvent content were 2.21 A3 Da(-1) and 44.6%, respectively, assuming the presence of two molecules in the asymmetric unit. Diffraction data were collected to a resolution of 1.8 A at the Swiss Light Source beamline X06SA using a MAR CCD area detector and gave a data set with an overall Rmerge of 6.8% and a completeness of 91.1%.

Characterization of two isoforms of mouse 3(17)alpha-hydroxysteroid dehydrogenases of the aldo-keto reductase family.

Mouse kidney contains two 3(17)alpha-hydroxysteroid dehydrogenases (HSDs) that show essentially the same properties except for their isoelectric points. However, the structural differences and physiological roles of the two enzymes remain unknown. In this study, we have isolated cDNAs for the two 3(17)alpha-HSDs from a total RNA sample of mouse kidney by reverse transcription-PCR. The identity of the cDNAs was confirmed by characterization of the recombinant enzymes that showed the same molecular weights, pI values, pH optima, substrate specificity and inhibitor sensitivity as those of the enzymes from mouse kidney. We also found that the recombinant enzymes reduce precursors of neuroactive progesterone derivatives, 5alpha-dihydrotestoserone, deoxycorticosterone, dehydroepiandrosterone, dehydroepiandrosterone sulfate and estrone at low Km values of 0.3-2 microM. The two enzymes belonged to the aldo-keto reductase (AKR) family, and their 323-amino acid sequences differed only by five amino acids. The sequences of the two isoforms are identical to those of proteins that are predicted to be encoded in a gene for AKR1C21 in the database of the mouse genome. However, the mRNAs for the two isoforms were expressed in mouse kidney and other tissues, in which their expression levels were different. The results indicate an important role of 3(17)alpha-HSD in controlling the concentrations of various steroid hormones in the mouse tissues, and suggest the existence of two genes for the two isoforms of the enzyme.

Crystallization and preliminary crystallographic analysis of human L-xylulose reductase.

Human L-xylulose reductase was crystallized from buffered polyethylene glycol solutions using the hanging-drop vapour-diffusion method. The crystals diffract to 2.1 A resolution and belong to the orthorhombic P222 space group, with unit-cell parameters a = 72.9, b = 74.1, c = 87.9 A. This is the first crystallization report of a xylulose reductase that is identical to diacetyl reductase.

Molecular characterization of mammalian dicarbonyl/L-xylulose reductase and its localization in kidney.

In this report, we first cloned a cDNA for a protein that is highly expressed in mouse kidney and then isolated its counterparts in human, rat hamster, and guinea pig by polymerase chain reaction-based cloning. The cDNAs of the five species encoded polypeptides of 244 amino acids, which shared more than 85% identity with each other and showed high identity with a human sperm 34-kDa protein, P34H, as well as a murine lung-specific carbonyl reductase of the short-chain dehydrogenase/reductase superfamily. In particular, the human protein is identical to P34H, except for one amino acid substitution. The purified recombinant proteins of the five species were about 100-kDa homotetramers with NADPH-linked reductase activity for alpha-dicarbonyl compounds, catalyzed the oxidoreduction between xylitol and l-xylulose, and were inhibited competitively by n-butyric acid. Therefore, the proteins are designated as dicarbonyl/l-xylulose reductases (DCXRs). The substrate specificity and kinetic constants of DCXRs for dicarbonyl compounds and sugars are similar to those of mammalian diacetyl reductase and l-xylulose reductase, respectively, and the identity of the DCXRs with these two enzymes was demonstrated by their co-purification from hamster and guinea pig livers and by protein sequencing of the hepatic enzymes. Both DCXR and its mRNA are highly expressed in kidney and liver of human and rodent tissues, and the protein was localized primarily to the inner membranes of the proximal renal tubules in murine kidneys. The results imply that P34H and diacetyl reductase (EC ) are identical to l-xylulose reductase (EC ), which is involved in the uronate cycle of glucose metabolism, and the unique localization of the enzyme in kidney suggests that it has a role other than in general carbohydrate metabolism.

Crystallization and preliminary X-ray diffraction analysis of monkey dimeric dihydrodiol dehydrogenase.

Dihydrodiol dehydrogenase catalyzes the NADP(+)-linked oxidation of trans-dihydrodiols of aromatic hydrocarbons to corresponding catechols and exists in multiple forms in mammalian tissues. The dimeric form of mammalian dihydrodiol dehydrogenase has a primary structure distinct from the previously known mammalian enzymes and may constitute a novel protein family with the prokaryotic proteins. Monkey kidney dimeric dihydrodiol dehydrogenase was crystallized from buffered ammonium phosphate solution using the hanging-drop vapour-diffusion method. The crystals diffract to 2.65 A resolution in the laboratory and belong to the hexagonal P6(1)22 or P6(5)22 space group, with unit-cell parameters a = b = 122.8, c = 121.3 A, alpha = beta = 90, gamma = 120 degrees.