UNIPROT:Q8NEX9 - FACTA Search

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Query: UNIPROT:Q8NEX9 (reductase)
26,410 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Dispersed rat pituitary cells were exposed to [1,2,6,7-3H]testosterone ([3H]T, 10(-8) M) to assess the role of 5 alpha-reduction in T regulation of gonadotroph secretion. After 4 to 48 hours of exposure, [3H]T metabolites isolated by thin-layer chromatography were characterized in medium and cell homogenates as well as bound to androgen receptors salt-extracted from purified nuclear pellets. Receptor-bound 5 alpha-[3H]dihydrotestosterone ([3H]DHT)/total [3H]androgens rose progressively from 16% at 4 hours to more than 50% at 48 hours. Coincubation with 4-MA (10- to 1,000-fold molar excess) or testosterone-17 beta-carboxylic acid (TCA; 1,000-fold excess) reduced receptor-bound [3H]DHT/[3H]androgen to less than 10% and 20%, respectively, but elevated [3H]T-receptor levels. Despite inhibiting 5 alpha-reductase activity, TCA and 4-MA had no effect on T suppression of gonadotropin-releasing hormone-stimulated luteinizing hormone secretion or T enhancement of total (cell + secreted) follicle-stimulating hormone levels. The results suggest that 5 alpha-reduction to DHT is not essential for the expression of the direct influences of T on gonadotropin synthesis and secretion in rat gonadotrophs.
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PMID:Testosterone processing by pituitary cells in culture: an examination of the role of 5 alpha-reduction in androgen action on the gonadotroph. 190 2

Trimethylamine oxide, which is found in relatively high concentrations in the tissues of marine animals, serves as an electron acceptor in the anaerobic metabolism of a number of bacteria associated primarily with three environments: the marine environment (e.g. Alteromonas and Vibrio), the brackish pond (nonsulfur photosynthetic bacteria), and animal intestines (Enterobacteriaceae). Its reduction to trimethylamine by such bacteria can constitute a major spoilage reaction during the storage of marine fish. In the Enterobacteriaceae, anaerobic respiration with TMAO has been shown to support oxidative phosphorylation. Electron transport to TMAO in these bacteria involves flavin nucleotides, menaquinones, both b- and c-type cytochromes, and a molybdoenzyme reductase. Formate, hydrogen, lactate, and glycerol all serve as electron donors for TMAO respiration. Electrophoretically distinct constitutive and TMAO-induced reductases are synthesized by both E. coli and S. typhimurium. Electron transport to TMAO is repressed both by air and by nitrate. A number of genes involved in TMAO respiration have been mapped, but the structural gene for the inducible TMAO reductase has not yet been firmly established. Oxidative phosphorylation is also supported by TMAO reduction in Alteromonas. In this organism, which is nonfermentative, TMAO respiration resembles aerobic respiration in that intermediates of the TCA cycle are excellent electron donors. Alteromonas exhibits a requirement for NaCl for growth on TMAO and certain electron donors. As in the Enterobacteriaceae, air and nitrate both interfere with TMAO reduction. The role of TMAO reduction in the anaerobic metabolism of nonsulfur purple bacteria has not yet been resolved; it is not clear if TMAO serves simply as an accessory oxidant for fermentation or if TMAO reduction is associated with energy-yielding membrane-bound electron transport. Some of the confusion regarding this bacterial group stems from the fact that much of the work to date has involved parallel studies of TMAO and dimethyl sulfoxide reduction, and it is not yet known whether the two compounds are reduced by the same enzyme. Although our understanding of bacterial TMAO reduction lags far behind our knowledge of bacterial nitrate reduction, it is unlikely that this will always be the case.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:Bacterial reduction of trimethylamine oxide. 390 97

We have previously shown that [2'-32P]-2-azido-NADP+ is an effective probe of the NADP-(H) binding site of rat liver microsomal 5 alpha-reductase (5 alpha R-1) [Bhattacharyya et al. (1994) Steroids 59, 634-641]. PEG-fractionated (6.5%) detergent-solubilized preparations (40 mg) containing 5 alpha R-1 activity were UV-photolyzed with [32P]-2-azido-NADP+ and subjected to preparative gel electrophoresis on 8% SDS-PAGE. Fractions corresponding to the second major [32P]-labeled peak following the dye-front were analyzed by 10% SDS-PAGE and showed a single [32P]-labeled species with an apparent molecular mass of approximately 26 kDa (5 alpha R-1). TCA precipitation (13.6%) of the labeled fractions resulted in recovery of > 70% of the total radioactivity in the protein pellet. Trypsin digestion of the resuspended pellet followed by immobilized-Al3+ affinity chromatography indicated that > 90% of the radioactivity remained bound to the affinity column. The [32P]-2N3-NADP(+)-labeled peptide was eluted with potassium phosphate, concentrated, and further purified by reverse-phase (C8) HPLC. Sequence analysis of the purified peptide indicated that it consisted of 11 amino acids with the sequence N-L-R-K-P-G-E-T-G-Y-K, corresponding to residues 170-180 of the rat 5 alpha R-1 sequence [Andersson et al. (1989) J. Biol. Chem. 264, 16249-16255].
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PMID:Identification of the NADP(H) binding site of rat liver microsomal 5 alpha-reductase (isozyme-1): purification of a photolabeled peptide corresponding to the adenine binding domain. 789 62

The mixed culture system was considered in the present research where sugars such as glucose were converted to lactate by Lactobacillus delbrueckii and the lactate was converted to poly beta-hydroxybutyrate (PHB) by Alcaligenes eutrophus in one fermentor. For the modeling of the effect of NH3 concentration on the cell growth of A. eutrophus and PHB production rates, metabolic flux distributions were computed at two culture phases of cell growth and PHB production periods. It was found that the NADPH, generated through isocitrate dehydrogenate in TCA cycle, was predominantly utilized for the reaction from alpha-ketoglutalate to glutamate when NH3 was abundant, while it tended to be utilized for the PHB production through acetoacetyl CoA reductase as NH3 concentration decreased. This phenomenon was reflected in the development of mathematical model. In the mixed culture experiments, the two phases were observed, namely the lactate production phase due to L. delbrueckii and the lactate consumption phase due to A. eutrophus. The lactate concentration could be estimated on-line by the amount of NaOH solution and HCl solution supplied to keep the culture pH at constant level. Several mixed culture experiments were conducted to see the dynamics of the system. Finally, a mathematical model which can describe the dynamic behavior of the present mixed culture was developed and the model parameters were tuned for fitting the experimental data. The model may be used for several purposes such as control, optimization, and understanding process dynamics etc.
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PMID:Dynamics and modeling on fermentative production of poly (beta-hydroxybutyric acid) from sugars via lactate by a mixed culture of Lactobacillus delbrueckii and Alcaligenes eutrophus. 999 Jul 31

In order to evaluate the ability of EMT6/Ro multicellular spheroids to utilize various pathways of energy production, (13)C and (31)P MRS have been employed to monitor the metabolism of glucose, glutamine, acetate and propionate. EMT6/Ro spheroids perfused with culture medium containing 5.5 mM glucose maintain stable levels of nucleotide triphosphates (NTP) and phosphocreatine (PCr) for up to 48 h, even in the absence of glutamine. The metabolism of 1-(13)C-glucose was almost entirely to 3-(13)C-lactate (88 +/- 12%, n = 7), even though the perfusion medium was equilibrated with 95% O(2). Labeling was also observed in other glycolytic metabolites, primarily alanine and alpha-glycerolphosphate. A low level of (13)C labeling in glutamate, indicative of mitochondrial oxidative metabolism (TCA cycle), was consistently detected when spheroids were perfused with 1-(13)C-glucose, almost exclusively in the C4 position of glutamate. Labeling of glutamate C2 and C3 was always less than 20% of the labeling in C4 and was usually undetectable. No evidence of adjacent carbon labeling in individual glutamate molecules (indicative of multiple cycles of label incorporation) was found, even in high-resolution (13)C NMR spectra of extracts from cells or spheroids. Despite the predominantly glycolytic metabolism of glucose, the mitochondrial substrate glutamine (2 mM, in the presence of < or =0.5 mM glucose from fetal bovine serum), supported stable levels of NTP and PCr in the tumor cells for up to 12 h. In the presence of 2.5 mM acetate, the bioenergetic status of cells in EMT6 spheroids declined slowly but measurably, and no incorporation of label from 2-(13)C-acetate into other metabolites was detected either in intact perfused spheroids or in high-resolution spectra of extracts. In contrast, when the anaplerotic TCA cycle substrate 3-(13)C-propionate replaced acetate, the high-energy phosphate levels in EMT6/Ro spheroids were somewhat reduced, but stabilized at a new lower level. Incubation of spheroids with 3-(13)C-propionate (with natural abundance glucose and glutamine) resulted in label detectable in the C2 and C3 of glutamate, but the primary labeled compound was methylmalonate, an intermediate in propionate metabolism. Addition of vitamin B(12), a cofactor for methylmalonyl CoA reductase, to the growth medium 24 h prior to perfusion with propionate resulted in the elimination of the methylmalonate resonance. A variety of 2- and 3-labeled metabolites were detected, including succinate, malate and glutamate. Labeling of C2 and C3 of lactate implicated cytoplasmic malic enzyme activity.
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PMID:Metabolism of alternative substrates and the bioenergetic status of EMT6 tumor cell spheroids. 1100 14

In vitro formation of the (35)S-labeled Fe-S cluster of ferredoxin (Fd) has been achieved by incubating apo-Fd and [(35)S]cysteine with osmotically lysed chloroplasts of spinach (Spinacia oleracea). Correct integration of the (35)S-labeled Fe-S cluster into Fd was verified on the basis of the following: (a) Under nondenaturing conditions, (35)S-labeled holo-Fd showed the same electrophoretic mobility as authentic holo-Fd; (b) (35)S-labeled holo-Fd showed an ability to bind Fd-NADP(+) reductase; (c) the (35)S-labeled moiety was removed from the Fd polypeptide by TCA treatment but not by 2-mercaptoethanol treatment; (d) externally added pea II apo-Fd was converted to (35)S-labeled holo-Fd. This reconstitution was dependent on both ATP and light, and formation of the (35)S-labeled Fe-S cluster was observed upon addition of ATP or when an ATP generation-system was constructed in the light. In contrast, ATP-consuming systems abolished the Fe-S cluster formation. A non-hydrolyzable ATP analog was unable to serve as an ATP substitute, indicating the requirement of ATP hydrolysis for cluster formation. GTP was able to substitute for ATP, but CTP and UTP were less effective. Fe-S cluster formation in lysed chloroplasts was stimulated by light even in the presence of added ATP. Light stimulation was inhibited by DCMU or methyl viologen but not by NH(4) (+). NADPH was able to substitute for light, indicating that light energy is required for the production of reducing compounds such as NADPH in addition to the generation of ATP. These results confirm the requirement of light for the Fe-S cluster formation observed previously in intact chloroplasts.
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PMID:Formation of the fe-s cluster of ferredoxin in lysed spinach chloroplasts. 1666 87

Fe (cellular iron), O (dioxygen, antioxidant inducers, hydrogen peroxide), and P (protein phosphorylation) signals combine to regulate DNA activity (transcription/mRNA synthesis) for antioxidant/Phase II response proteins (e.g., ferritin H, ferritin L, thioredoxin reductase I, NAD(P)H quinone oxido-reductase, heme oxygenase1 and beta-globin) and mRNA activity for proteins of iron transport, storage or oxygen metabolism (e.g., ferritin H, ferritin L, transferrin receptor1, ferroportin, mt-aconitase-TCA cycle and aminolevulinate synthase - heme biosynthesis). Ferritin regulation links the two groups of genetic controls via DNA (ARE-antioxidant response element) and mRNA (IRE-iron responsive element) structures. More is known about the IRE-mRNA and protein repressors, IRPs (iron regulatory proteins/aconitase homologues), than the DNA-ARE and protein repressors, e.g., Bach1. Iron responsive elements are very similar (65-80% sequence identity), but each mRNA has sufficient IRE specificity (>90% phylogenetic sequence conservation), that IRP binding and signal responses vary quantitatively. The structural specificity of each IRE-RNA provides an opportunity for finding small molecule regulators in vitro, and possibly in vivo. The potential of manipulating mRNA function with small molecules targeted to specific RNA regulatory structures, e.g., ferritin mRNA in iron overload, or viral mRNA control structures for replication, is high.
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PMID:Integrating iron and oxygen/antioxidant signals via a combinatorial array of DNA - (antioxidant response elements) and mRNA (iron responsive elements) sequences. 1708 1

Proline metabolism in mammals involves two other amino acids, glutamate and ornithine, and five enzymatic activities, Delta(1)-pyrroline-5-carboxylate (P5C) reductase (P5CR), proline oxidase, P5C dehydrogenase, P5C synthase and ornithine-delta-aminotransferase (OAT). With the exception of OAT, which catalyzes a reversible reaction, the other four enzymes are unidirectional, suggesting that proline metabolism is purpose-driven, tightly regulated, and compartmentalized. In addition, this tri-amino-acid system also links with three other pivotal metabolic systems, namely the TCA cycle, urea cycle, and pentose phosphate pathway. Abnormalities in proline metabolism are relevant in several diseases: six monogenic inborn errors involving metabolism and/or transport of proline and its immediate metabolites have been described. Recent advances in the Human Genome Project, in silico database mining techniques, and research in dissecting the molecular basis of proline metabolism prompted us to utilize functional genomic approaches to analyze human genes which encode proline metabolic enzymes in the context of gene structure, regulation of gene expression, mRNA variants, protein isoforms, and single nucleotide polymorphisms.
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PMID:Functional genomics and SNP analysis of human genes encoding proline metabolic enzymes. 1850 9

Escherichia coli strain PC09 (DeltaxylB, cAMP-independent CRP (crp*) mutant) expressing an NADPH-dependent xylose reductase from Candida boidinii (CbXR) was previously reported to produce xylitol from xylose while metabolizing glucose [Cirino et al. (2006) Biotechnol Bioeng 95(6): 1167-1176]. This study aims to understand the role of NADPH supply in xylitol yield and the contribution of key central carbon metabolism enzymes toward xylitol production. Studies in which the expression of CbXR or a xylose transporter was increased suggest that enzyme activity and xylose transport are not limiting xylitol production in PC09. A constraints-based stoichiometric metabolic network model was used to understand the roles of central carbon metabolism reactions and xylose transport energetics on the theoretical maximum molar xylitol yield (xylitol produced per glucose consumed), and xylitol yields (Y(RPG)) were measured from resting cell biotransformations with various PC09 derivative strains. For the case of xylose-proton symport, omitting the Zwf (glucose-6-phosphate dehydrogenase) or PntAB (membrane-bound transhydrogenase) reactions or TCA cycle activity from the model reduces the theoretical maximum yield from 9.2 to 8.8, 3.6, and 8.0 mol xylitol (mol glucose)(-1), respectively. Experimentally, deleting pgi (encoding phosphoglucose isomerase) from strain PC09 improves the yield from 3.4 to 4.0 mol xylitol (mol glucose)(-1), while deleting either or both E. coli transhydrogenases (sthA and pntA) has no significant effect on the measured yield. Deleting either zwf or sucC (TCA cycle) significantly reduces the yield from 3.4 to 2.0 and 2.3 mol xylitol (mol glucose)(-1), respectively. Expression of a xylose reductase with relaxed cofactor specificity increases the yield to 4.0. The large discrepancy between theoretical maximum and experimentally determined yield values suggests that biocatalysis is compromised by pathways competing for reducing equivalents and dissipating energy. The metabolic role of transhydrogenases during E. coli biocatalysis has remained largely unspecified. Our results demonstrate the importance of direct NADPH supply by NADP+-utilizing enzymes in central metabolism for driving heterologous NADPH-dependent reactions, and suggest that the pool of reduced cofactors available for biotransformation is not readily interchangeable via transhydrogenase.
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PMID:Analysis of NADPH supply during xylitol production by engineered Escherichia coli. 1869 48

Erythritol is an important sugar alcohol industrially produced only by fermentation. The highly osmophilic yeast-like fungi, Trichosporonoides megachiliensis SN-G42, enables commercial production of erythritol with a high conversion from glucose to erythritol of more than 47%. However, the microbial production pathway of erythritol remains unclear. In the present study, the activities of enzymes in the pentose phosphate pathway of Trichosporonoides megachiliensis SN-G42 used for industrial erythritol production were measured under various culture conditions to examine the production mechanism and the key-enzymes. As a result, the various enzyme activities of this organism are revealed in the pentose phosphate pathway, i.e., those of hexokinase, glucose-6-phosphate dehydrogenase, gluconate dehydrogenase, transketolase, transaldolase, and erythrose reductase. In the cultures in which erythritol was produced after completion of cell growth, the enzyme activities of the pentose phosphate pathway were higher than those of the TCA cycle. In particular, transketolase activity was correlated with erythritol productivity under various production cultures with different agitation speeds and thiamine concentrations. These results suggest that erythritol may be produced mainly through the pentose phosphate pathway. In addition, the high activity of transketolase is required to produce abundant intermediates, which results in high erythritol productivity. As such, transketolase appears to be a key-enzyme for erythritol production in the organism studied.
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PMID:Key role for transketolase activity in erythritol production by Trichosporonoides megachiliensis SN-G42. 1980 61

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