Lucie Skarydova

Human microsomal carbonyl reducing enzymes in the metabolism of xenobiotics: well-known and promising members of the SDR superfamily

The best known, most widely studied enzyme system in phase I biotransformation is cytochrome P450 (CYP), which participates in the metabolism of roughly 9 of 10 drugs in use today. The main biotransformation isoforms of CYP are associated with the membrane of the endoplasmatic reticulum (ER). Other enzymes that are also active in phase I biotransformation are carbonyl reducing enzymes. Much is known about the role of cytosolic forms of carbonyl reducing enzymes in the metabolism of xenobiotics, but their microsomal forms have been mostly poorly studied. The only well-known microsomal carbonyl reducing enzyme taking part in the biotransformation of xenobiotics is 11β-hydroxysteroid dehydrogenase 1, a member of the short-chain dehydrogenase/reductase superfamily. Physiological roles of microsomal carbonyl reducing enzymes are better known than their participation in the metabolism of xenobiotics. This review is a summary of the fragmentary information known about the roles of the microsomal forms. Besides 11β-hydroxysteroid dehydrogenase 1, it has been reported, so far, that retinol dehydrogenase 12 participates only in the detoxification of unsaturated aldehydes formed upon oxidative stress. Another promising group of microsomal biotransformation carbonyl reducing enzymes are some members of 17β-hydroxysteroid dehydrogenases. Generally, it is clear that this area is, overall, quite unexplored, but carbonyl reducing enzymes located in the ER have proven very interesting. The study of these enzymes could shed new light on the metabolism of several clinically used drugs or they could become an important target in connection with some diseases.

Anthracyclines and their metabolism in human liver microsomes and the participation of the new microsomal carbonyl reductase.

Anthracyclines (ANTs) are widely used in the treatment of various forms of cancer. Although their usage contributes to an improvement in life expectancy, it is limited by severe adverse effects-acute and chronic cardiotoxicity. Several enzymes from both AKR and SDR superfamilies have been reported as participants in the reduction of ANTs. Nevertheless all of these are located in the cytosolic compartment. One microsomal reductase has been found to be involved in the metabolism of xenobiotics-11beta-HSD1, but no further information has been reported about its role in the metabolism of ANTs. The aim of this study is to bring new information about the biotransformation of doxorubicin (DOX), daunorubicin (DAUN) and idarubicin (IDA), not only in human liver microsomal fraction, but also by a novel human liver microsomal carbonyl reductase that has been purified by our group. The reduction of ANTs at C-13 position is regarded as the main pathway in the biotransformation of ANTs. However, our experiments with human liver microsomal fraction show different behaviour, especially when the concentration of ANTs in the incubation mixture is increased. Microsomal fraction was incubated with doxorubicin, daunorubicin and idarubicin. DOX was both reduced into doxorubicinol (DOXOL) and hydrolyzed into aglycone DOX and then subsequently reduced. The same behaviour was observed for the metabolism of DAUN and IDA. The activity of hydrolases definitely brings a new look to the entire metabolism of ANTs in microsomal fraction, as formed aglycones undergo reduction and compete for the binding site with the main ANTs. Moreover, as there are two competitive reducing reactions present for all three ANTs, kinetic values of direct reduction and the reduction of aglycone were calculated. These results were compared to previously published data for human liver cytosol. In addition, the participation of the newly determined human liver microsomal carbonyl reductase was studied. No reduction of DOX into DOXOL was detected. Nevertheless, the involvement in reduction of DAUN into DAUNOL as well as IDA into IDAOL was demonstrated. The kinetic values obtained were then compared with data which have already been reported for cytosolic ANTs reductases.

Role of carbonyl reducing enzymes in the phase I biotransformation of the non-steroidal anti-inflammatory drug nabumetone in vitro

1. Nabumetone is a clinically used non-steroidal anti-inflammatory drug, its biotransformation includes major active metabolite 6-methoxy-2-naphtylacetic acid and another three phase I as well as corresponding phase II metabolites which are regarded as inactive. One important biotransformation pathway is carbonyl reduction, which leads to the phase I metabolite, reduced nabumetone. 2. The aim of this study is the determination of the role of a particular human liver subcellular fraction in the nabumetone reduction and the identification of participating carbonyl reducing enzymes along with their stereospecificities. 3. Both subcellular fractions take part in the carbonyl reduction of nabumetone and the reduction is at least in vitro the main biotransformation pathway. The activities of eight cytosolic carbonyl reducing enzymes – CBR1, CBR3, AKR1B1, AKR1B10, AKR1C1-4 – toward nabumetone were tested. Except for CBR3, all tested reductases transform nabumetone to its reduced metabolite. AKR1C4 and AKR1C3 have the highest intrinsic clearances. 4. The stereospecificity of the majority of the tested enzymes is shifted to the production of an (+)-enantiomer of reduced nabumetone; only AKR1C1 and AKR1C4 produce predominantly an (−)-enantiomer. This project provides for the first time evidence that seven specific carbonyl reducing enzymes participate in nabumetone metabolism.

Biochemical properties of human dehydrogenase/reductase (SDR family) member 7.

Dehydrogenase/reductase (SDR family) member 7 (DHRS7, retSDR4, SDR34C1) is a previously uncharacterized member of the short-chain dehydrogenase/reductase (SDR) superfamily. While human SDR members are known to play an important role in various (patho)biochemical pathways including intermediary metabolism and biotransformation of xenobiotics, only 20% of them are considered to be well characterized. Based on phylogenetic tree and SDR sequence clusters analysis DHRS7 is a close relative to well-known SDR member 11β-hydroxysteroid dehydrogenase 1 (11β-HSD1) that participates in metabolism of endogenous and xenobiotic substances with carbonyl group. The aim of present study is to determine the basic biochemical properties of DHRS7 and its possible involvement in metabolism of substrates with carbonyl group. For the first time the computational predictions of this membrane protein and membrane topology were experimentally confirmed. DHRS7 has been demonstrated to be an integral protein facing the lumen of the endoplasmic reticulum with lack of posttranscriptional glycosylation modification. Subsequently, NADP(H) cofactor preference and enzymatic reducing activity of DHRS7 was determined towards endogenous substrates with a steroid structure (cortisone, 4-androstene-3,17-dion) and also toward relevant exogenous substances bearing a carbonyl group harmful to human health (1,2-naphtoquinone, 9,10-phenantrenequinone). In addition to 11β-HSD1, DHRS7 is another enzyme from SDR superfamily that have been proved, at least in vitro, to contribute to the metabolism of xenobiotics with carbonyl group.

Isoquinoline alkaloids as a novel type of AKR1C3 inhibitors

AKR1C3 is an important human enzyme that participates in the reduction of steroids and prostaglandins, which leads to proliferative signalling. In addition, this enzyme also participates in the biotransformation of xenobiotics, such as drugs and procarcinogens. AKR1C3 is involved in the development of both hormone-dependent and hormone-independent cancers and was recently demonstrated to confer cell resistance to anthracyclines. Because AKR1C3 is frequently upregulated in various cancers, this enzyme has been suggested as a therapeutic target for the treatment of these pathological conditions. In this study, nineteen isoquinoline alkaloids were examined for their ability to inhibit a recombinant AKR1C3 enzyme. As a result, stylopine was demonstrated to be the most potent inhibitor among the tested compounds and exhibited moderate selectivity towards AKR1C3. In the follow-up cellular studies, stylopine significantly inhibited the AKR1C3-mediated reduction of daunorubicin in intact cells without considerable cytotoxic effects. This inhibitor could therefore be used as a model AKR1C3 inhibitor in research or evaluated as a possible therapeutic anticancer drug. Furthermore, based on our results, stylopine can serve as a model compound for the design and future development of structurally related AKR1C3 inhibitors.

Partial purification and characterization of a new human membrane-bound carbonyl reductase playing a role in the deactivation of the anticancer drug oracin

Carbonyl reducing enzymes play important roles in the biotransformation and detoxification of endo- and xenobiotics. They are grouped into two protein superfamilies, the short-chain dehydrogenases (SDR) and aldo-keto reductases (AKR), and usually are present in the cytoplasm of a cell. So far, only one membraneous carbonyl reductase has been described, 11beta-hydroxysteroid dehydrogenase type 1 (11beta-HSD1), which is located in the endoplasmic reticulum and which significantly contributes to the metabolism of a variety of carbonyl containing drugs and toxicants. Oracin is a new and prospective anticancer drug bearing a prochiral carbonyl moiety. The main metabolic pathway of oracin is carbonyl reduction to 11-dihydrooracin (DHO) which, however, eliminates the therapeutic potential of the drug, because the two DHO enantiomers formed have significantly less anti-tumor activities. Therefore, the oracin inactivating enzymes should urgently be identified to search for specific inhibitors and to enhance the chemotherapeutic efficacy. Interestingly, the calculation of enzyme specific activities and stereospecificities of (+)-DHO and (-)-DHO formation strongly suggested the existence of a second, hitherto unknown microsomal oracin carbonyl reductase in human liver. Therefore, the aim of the present study was to provide proof for the existence of this new enzyme and to develop a purification method for further characterization. First, we succeeded in establishing a gentle solubilization technique which provided a favourable detergent surrounding during the further purification procedure by stabilizing the native form of this fragile protein. Second, we could partially purify this new microsomal carbonyl reductase by a two step separation on Q-sepharose followed by Phenyl-sepharose. The enzyme turned out to be NADPH specific, displaying kinetic values for oracin carbonyl reduction of K(m)=42 microM and V(max)=813 nmol/(30 min x mg protein). Compared to the microsomal fraction, the enzyme specific activity towards oracin could be enhanced 73-fold, while the stereospecificity of (+)-DHO formation shifted from 40% to 86%. Considering these data for 11beta-HSD1, as described in previous reports, it is clear that the microsomal carbonyl reductase investigated in the present study is new and has a great potential to significantly impair the chemotherapy with the new anticancer drug oracin.

Purification and reconstitution of human membrane-bound DHRS7 (SDR34C1) from Sf9 cells

Dehydrogenase/reductase SDR family member 7 (DHRS7, SDR34C1, retSDR4) is one of the many endoplasmic reticulum bound members of the SDR superfamily. Preliminary results indicate its potential significance in human metabolism. DHRS7 containing TEV-cleavable His10 and FLAG-tag expressed in the Sf9 cell line was solubilised, purified, and reconstituted into liposomes to enable the improved characterisation of this enzyme in the future. Igepal CA-630 was determined to be the best detergent for the solubilisation process. The solubilised DHRS7 was purified using affinity chromatography, and the purified enzyme was subjected to TEV cleavage of the affinity tags and then repurified using subtractive Ni-IMAC. The cleaved and uncleaved versions of DHRS7 were successfully reconstituted into liposomes. In addition, using tobacco specific carcinogen 4-(methylnitrosamino)-1-(3-pyridyl)-1-butanone (NNK) as the substrate, the cleaved liposomal DHRS7 was found to be inactive, whereas the pure and uncleaved liposomal DHRS7 were confirmed as enzymes, which reduce carbonyl group of the substrates.

A Simple Identification of Novel Carbonyl Reducing Enzymes in the Metabolism of the Tobacco Specific Carcinogen NNK

Tobacco smoking is the most widely known cause of human cancer-related death worldwide. NNK is one of the proved human carcinogens contributing to the development of several types of cancer. The carcinogenic effect of NNK depends on the metabolic pathway. Reduction of NNK by carbonyl reducing enzymes leads to the formation of NNAL. This pathway is generally regarded as detoxification pathway although the conditions and circumstances are quite complicated - the process depends on a formed enantiomer of NNAL. In this study a novel method for the determination of the metabolite NNAL was developed. This makes it possible to findand characterize carbonyl reducing enzymes that are involved in NNK metabolism. This simple HPLC method uses conventional HPLC instrumentation and is designed mainly for biochemical laboratories. A new microsomal carbonyl reducing enzyme participating in the metabolism of NNK in vitro has been described. Its activity was compared with other carbonyl reducing enzymes taking part in the biotransformation of NNK.

Imbalance in redox system of rat liver following permethrin treatment in adolescence and neonatal age

Abstract 1.  The effect of different permethrin treatments on the redox system of rat liver, is presented. Two types of oral administration were chosen: (i) sub-chronic treatment (1/10 of LD50 for 60 days) during adolescence (5 weeks old) and (ii) sub-acute treatment (1/44 of LD50 for 15 days) during early life (from postnatal days 6–21). 2.  The results show that adolescent permethrin treatment induces damage to the liver redox system, increasing lipid and protein peroxidation and reducing membrane fluidity in the hydrophilic--hydrophobic region of the bilayer. In addition, glutathione peroxidase (GPx) and GSH levels resulted decreased, while glutathione transferase (GST) and catalase (CAT) levels increased. 3.  The rats treated in early life with permethrin and sacrificed in adult age, showed less signs of damage compared to those exposed during adolescence in which lipid peroxidation was increased by 32%, whereas for the first group the raise was only 11%. Moreover, fluidity improved in the deeper hydrophobic membrane region of the treated group, while the level of CAT was significantly lower compared to the control one. 4.  Although sub-chronic treatment increased CAT and GST and decreased GPx and GSH levels, the present data suggest that a shorter exposure to permethrin during neonatal age decreased CAT level and it could represent an important risk factor for the onset of long-term liver damage.

Enzyme stereospecificity as a powerful tool in searching for new enzymes.

Chirality is a ubiquitous feature present in all biological systems that plays a very important role in many processes. Drug metabolism is one of these and is the subject of this review. Chiral drugs can be metabolized without changes in their chiral characteristics, but also their biotransformation may give rise to a new chiral center. On the other hand, prochiral drugs are always metabolized to chiral metabolites. The ratio of formed enantiomers/diastereoisomers is the constant known as enzyme stereospecificity, and this is as important a characteristic for each enzyme-substrate pair as is the Michaelis constant. Drugs are often substrates for multiple biotransformation enzymes, and all enzymes involved may metabolize a chiral or prochiral drug with different stereospecificity so that variant enantiomer ratios are achieved. Enzyme stereospecificity of whole cell fraction is the sum of the stereospecificities of all enzymes participating in metabolism of a substrate. Differing stereospecificities in the metabolism of a drug between whole cell fraction and enzymes point to the contribution of other enzymes. Using several drugs as examples, this review shows that enzyme stereospecificity can serve as a powerful tool in searching for new biotransformation enzymes. Although it is not often used in this way, it is clear that this is possible. There are today drugs with well-known chiral metabolism, but, inasmuch as many xenobiotics are poorly characterized in terms of chiral metabolism, enzyme stereospecificity could be widely utilized in researching such substances.