p-Chlorphenylalanine effect on phenylalanine hydroxylase in hepatoma cells in culture.

We have investigated the p-chlorophenylalanine-dependent loss of phenylalanine hydroxylase activity in cultured hepatoma cells. The similarity of the effect of p-chlorophenylalanine on phenylalanine hydroxylase in the hepatoma cells and that reported from studies in vivo indicates that the loss of phenylalanine hydroxylase activity is due to a direct interaction of the amino acid analogue with the liver. We can find no evidence that the loss of phenylalanine hydroxylase activity is due to: a direct inactivation of the hydroxylase by p-chlorophenylalanine or an inhibitor produced by p-chlorophenylalanine treatment; an effect similar to that of p-fluorophenylalanine; or leakage of enzyme from the cells during p-chlorophenylalanine treatment. The data presented indicate: (a) the p-chlorophenylalanine effect is rather specific for phenylalanine hydroxylase; (b) following p-chlorophenylalanine removal, new protein synthesis is necessary for restoration of the hydroxylase activity; (c) the rate of loss of phenylalanine hydroxylase activity after the addition of p-chlorophenylalanine is much faster than the rate of restoration of the hydroxylase activity after removal of p-chlorophenylalanine; (d) even in the presence of p-chlorophenylalanine, hydrocortisone greatly stimulates the hydroxylase activity; (e) the cell density-dependent increase of phenylalanine hydroxylase activity is blocked by p-chlorophenylalanine. A discussion of the possible mechanisms of p-chlorophenylalanine-dependent loss of phenylalanine hydroxylase is presented. To measure very low leanine-dependent loss of phenylalanine hydroxylase is presented. To measure very low levels of phenylalanine hydroxylase activity, a new procedure, based on isotope dilution, was developed for isolating the tyrosine formed during the enzymatic reaction.     

The mechanism of the irreversible inhibition ofrat liver phenylalanine hydroxylase due to treatment with p-chlorophenylalanine. The lack of effect on turnover of phenylalanine hydroxylase.

The administration of a single dose of p-chlorophenylalanine (360 mg/kg) to rats leads to the irreversible loss of 90% of hepatic phenylalanine hydroxylase activity after 24 h. This loss of activity is not the result of either an alteration in the overall structure of the enzyme, as determined by its antigenicity, or in the total immunologically reactive protein in the liver, as tested with a specific antiserum prepared against native phenylalanine hydroxylase. Neither the rate of synthesis nor the rate of degradation of phenylalanine hydroxylase is changed by p-chlorophenylalanine (pClPhe) treatment. The half-life for the enzyme is about 2 days in control and in pClPhe-treated rats. In addition, there is no detectable incorporation of pClPhe into the phenylalanine hydroxylase molecule itself.     

Reversible inactivation of phenylalanine hydroxylase by catecholamines in cultured hepatoma cells.

Phenylalanine hydroxylase in Reuber H4 hepatoma cell cultures can be rapidly inactivated by the addition of epinephrine, norepinephrine, dopamine, or 3,4-dihydroxyphenylalanine, in order of decreasing effectiveness, to the culture medium. The enzyme was 50% inactivated in 1 hour by 25 muM (R)-epinephrine or 45 muM (R)-norepinephrine in the medium. High concentrations of epinephrine caused a 70% inactivation in 15 min. Phenylalanine hydroxylase appears to be reversibly inactivated by epinephrine within the cells; since washing the compound off the cell cultures resulted in a rapid restoration of enzyme activity (40% in 1 hour), cycloheximide had little effect on the initial rate of recovery of enzyme activity and the same amount of phenylalanine hydroxylase antigen per cell was isolated from treated and normal cultures. Both (S)- and (R)-epinephrine inactivated the enzyme, and 0.1 mM desmethylimipramine, an inhibitor of amine transport, significantly decreased the effect of epinephrine on the hydroxylase activity. The possibility, suggested by the above results, that epinephrine might be directly inactivating phenylalanine hydroxylase within the cells was supported by the finding that purified rat liver phenylalanine hydroxylase would be 50% inactivated by 1.5 muM epinephrine in 10 min.     

The regulation of phenylalanine hydroxylase in rat tissues in vivo. Substrate- and cortisol-induced elevations in phenylalanine hydroxylase activity.

Injections of phenylalanine increased a 2.5-fold in 9 h the hepatic phenylalanine hydroxylase activity of 6-day-old or adult rats that had been pretreated (24h earlier) with p-chlorophenylalanine; without such pretreatment, phenylalanine did not raise the enzyme concentration. This difference is paralleled by the much greater extent to which the injected phenylalanine accumulated in livers of the pretreated compared with the normal animals. The hormonal induction of hepatic phenylalanine hydroxylase activity obeyed different rules: an injection of cortisol was without effect on adult livers but caused a threefold rise in phenylalanine hydroxylase activity of immature ones, both without and after pretreatment with p-chlorophenylalanine. In the latter instance, the effects of cortisol, and of phenylalanine were additive. Actinomycin inhibited the cortisol- but not the substrate-induced increase of phenylalanine hydroxylase, whereas puromycin inhibited both. The results indicate that substrate and hormone, two potential positive regulators of the amount of the hepatic (but not the renal) phenylalanine hydroxylase, act independently by two different mechanisms. The negative effector, p-chlorophenylalanine, also appears to interact with the synthetic (or degradative) machinery rather than with the existing phenylalanine hydroxylase molecules: 24h were required in vivo for an 85% decrease to ensue, and no inhibition occurred in vitro when incubating the enzyme with p-chlorophenylalanine or with liver extracts from p-chlorophenylalanine-treated rats.     

Evaluation of histochemical observations of activity of acid hydrolases obtained with semipermeable membrane techniques. 3. The substrate specificity of isoenzymes of acid phosphatase in m.gastrocnemius of rabbits.

Three distinct isoenzymes of acid phosphatase have been separated from extracts of m.gastrocnemius of normal and of vitamin E deficient rabbits by gel filtration and polyacrylamide gel electrophoresis. These isoenzymes, termed I, II and III, have molecular weights of: 110,000--130,000, 60,000--78,000 and 12,500--14,500. Isoenzymes I and II split the substrates 4-methylumbelliferyl phosphate and naphthol AS-BI phosphate and the activity is strongly increased in the muscles of vitamin E deficient rabbits. Isoenzyme III splits only 4-methylumbelliferyl phosphate and the activity is not increased in the muscles of vitamin E deficient rabbits. The pH-optimum for isoenzymes I and II is 4.8 and for isoenzyme III 5.5. It has been shown that the histochemical semipermeable membrane technique, using substrate naphthol AS-BI phosphate, is a very reliable technique for demonstrating activity of the isoenzymes I and II in tissue sections. On the other hand, activity of isoenzyme III cannot be demonstrated with this histochemical technique. In pathologically altered muscles, the activity of the isoenzymes I and II is greatly increased whilst the activity of isoenzyme III is not significantly altered.     

Genetics of the mammalian phenylalanine hydroxylase system. IV. Evidence of phenylalanine hydroxylase in a cultured human hepatoma cell line

We report here the identification of a cultured human hepatoma cell line which possesses an active phenylalanine hydroxylase system. Phenylalanine hydroxylation was established by growth of cells in a tyrosine-free medium and by the ability of a cell-free extract to convert [¹⁴C]phenylalanine to [¹⁴C]tyrosine in an enzyme assay system. This enzyme activity was abolished by the presence in the assay system of p-chlorophenylalanine but no significant effect on the activity was observed with 3-iodotyrosine and 6-fluorotryptophan. Use of antisera against pure monkey or human liver phenylalanine hydroxylase has detected a cross-reacting material in this cell line which is antigenically identical to the human liver enzyme. Phenylalanine hydroxylase purified from this cell line by affinity chromatography revealed a multimeric molecular weight (estimated 275,000) and subunit molecular weights (estimated 50,000 and 49,000) which are similar to those of phenylalanine hydroxylase purified from a normal human liver. This cell line should be a useful tool for the study of the human phenylalanine hydroxylase system.     

Cytosolic and mitochondrial isoenzymes of branched-chain amino acid aminotransferase during development of the rat.

The isoenzymic forms of branched-chain amino acid aminotransferase in mitochondria of rat tissues were compared with the better-known cytosolic forms in order to find any regular pattern of expression of these isoenzymes during development. Mitochondria of all tissues examined except brain contained only a type-I isoenzyme differing from the cytosolic type-I isoenzyme in heat stability and activation by mercaptoethanol. Foetal and adult brain mitochondria contained isoenzymes type III as well as type I. The large excess of type-I isoenzyme in foetal liver was localized in mitochondria, apparently of haematopoietic cells. The activity of this isoenzyme declined precipitously (by 80%) from day 19 of gestation at the same period and rate as does the volume fraction of haematopoietic cells that are then leaving the liver. Cortisol treatment accelerated the loss of these cells, and proportionally accelerated loss of the mitochondrial isoenzyme I. A development succession of type-I isoenzyme by the unique type II of liver parenchymal cell cytosols could not be demonstrated, since small, about equal, amounts of types I and II were always present in cytosols of foetal and adult liver. Developmental succession of isoenzymes within tissues was limited to cytosols and was demonstrated by the presence of cytosolic isoenzyme III in foetal and newborn skeletal muscle and kidney, organs which contain only isoenzyme I in the adult.     

Dimeric nature and amino acid compositions of homogeneous canine prostatic human liver and rat liver acid phosphatase isoenzymes. Specificity and pH-dependence of the canine enzyme.

Two isoenzymes of rat liver acid phosphatase (orthophosphoric-monoester phosphohydrolase (acid optimum) EC 3.1.3.2) have been purified to homogeneity, at least one of these for the first time. Both of the rat liver isoenzymes have identical specific activities towards p-nitrophenyl phosphate. Molecular weights of the native enzymes are 92 000 for rat liver isoenzyme I and 93 000 for isoenzyme II, while the subunit molecular weights are 51 000 and 52 000 respectively. Data on substrate specificity and pH dependence are presented for the homogeneous canine prostatic enzyme, which is also isolated as a dimeric enzyme of (native) molecular weight 89 000. Carbohydrate analysis data are presented for canine prostatic acid phosphatase and it is further noted that both isoenzymes of rat liver acid phosphatase are also glycoproteins. The amino acid compositions of the two rat liver isoenzymes are presented together with those of the similar dimeric acid phosphatase of human liver and of canine prostate. Comparison of these results with published data for the amino acid composition of human prostatic acid phosphatase shows substantial similarities. However, significant differences are seen in the amino acid composition of rat liver acid phosphatase isoenzyme I as compared to a previous literature report. Most notably, 17 histidine residues are found per mol of isoenzyme I and 18 for isoenzyme II.     

Effect of glucagon on phenylalanine metabolism and phenylalanine-degrading enzymes in the rat

Glucagon administered subcutaneously to rats for 10 days had no significant effect on liver phenylalanine hydroxylase activity, but induced liver dihydropteridine reductase more than twofold. In rats administered a phenylalanine load orally, glucagon treatment stimulated oxidation and depressed urinary phenylalanine excretion. These responses could not be related to an effect of glucagon on hepatic tyrosine-alpha-oxoglutarate aminotransferase activity. Even in rats with phenylalanine hydroxylase activity depressed to 50% of control values by p-chlorophenylalanine administration, glucagon treatment increased the phenylalanine-oxidation rate substantially. Although hepatic phenylalanine-pyruvate aminotransferase was increased tenfold in glucagon-treated rats, glucagon treatment did not increase urinary excretion of phenylalanine transamination products by rats given a phenylalanine load. Glucagon treatment did not affect phenylalanine uptake by the gut or liver, or the liver content of phenylalanine hydroxylase cofactor. It is suggested that dihydropteridine reductase is the rate-limiting enzyme in phenylalanine degradation in the rat, and that glucagon may regulate the rate of oxidative phenylalanine metabolism in vivo by promoting indirectly the maintenance of the phenylalanine hydroxylase cofactor in its active, reduced state.     

The isolation and properties of phenylalanine hydroxylase from human liver

Phenylalanine hydroxylase was prepared from human foetal liver and purified 800-fold; it appeared to be essentially pure. The phenylalanine hydroxylase activity of the liver was confined to a single protein of mol.wt. approx. 108000, but omission of a preliminary filtration step resulted in partial conversion into a second enzymically active protein of mol.wt. approx. 250000. Human adult and full-term infant liver also contained a single phenylalanine hydroxylase with molecular weights and kinetic parameters the same as those of the foetal enzyme; foetal, newborn and adult phenylalanine hydroxylase are probably identical. The K(m) values for phenylalanine and cofactor were respectively one-quarter and twice those found for rat liver phenylalanine hydroxylase. As with the rat enzyme, human phenylalanine hydroxylase acted also on p-fluorophenylalanine, which was inhibitory at high concentrations, and p-chlorophenylalanine acted as an inhibitor competing with phenylalanine. Iron-chelating and copper-chelating agents inhibited human phenylalanine hydroxylase. Thiol-binding reagents inhibited the enzyme but, as with the rat enzyme, phenylalanine both stabilized the human enzyme and offered some protection against these inhibitors. It is hoped that isolation of the normal enzyme will further the study of phenylketonuria.     

Rhythmic variations in acid phosphatase activity in the liver of newborn rats

The rhythm of acid phosphatase activity in liver homogenates of newborn rats (aged about 14 days) was compared with a similar rhythm in adult rats (aged 4.5 months). Serial chromatographic investigations demonstrating isoenzyme patterns demonstrated age-related changes of this rhythm connected with the synthesis of the enzyme in newborn rats. The averaged activity of the enzyme in the liver homogenates of newborn rats was about 4 times lower than in adult rats. The maximal values of total enzyme activity of both isoenzymes after chromatographic separation in newborn rats were shifted by about 7 hours in relation to adult animals. Similar changes were observed in the case of the greatest maximal values of the activity ratios--subunit: both isoenzymes, and isoenzyme II: isoenzyme I. In adult rats these maximal values appeared during the night hours and in newborn rats during the day.     

Measurement of phenylalanine hydroxylase turnover in cultured hepatoma cells.

A substantially new method has been developed to measure protein turnover. Its basis is the notion that in labeling experiments a secreted protein can be used to determine the specific radioactivity of the intracellular amino acid precursor pool. To measure protein turnover in the Reuber hepatoma H4 cell line, cultures were labeled with [3H]leucine for specified periods after which phenylalanine hydroxylase was isolated and its leucine specific radioactivity determined. Serum albumin secreted by the cultures was also isolated and used to estimate the leucine precursor pool specific radioactivity. The protein half-life of phenylalanine hydroxylase could them be calculated. Experiments performed at long and short labeling times and with high and low concentrations of leucine in the medium yielded equivalent results. Phenylalanine hydroxylase half-life in the H4 cells was investigated under both normal and hydrocortisone-induced growth conditions. Average half-lives of 7.4 and 8.2 h were found for induced and uninduced cultures, respectively. Although these measured enzyme half-lives were not essentially different, the steady state level of phenylalanine hydroxylase was increased 6.2-fold upon hydrocortisone induction, from 0.076 to 0.47 microgram/10(6) cells. The results demonstrated that hydrocortisone induces phenylalanine hydroxylase in the H4 cells by causing an increase in the rate of enzyme synthesis.     

Purification and characterization of Cu-Zn superoxide dismutases from mungbean (Vigna radiata) seedlings

Mungbean contains three isoenzymes of superoxide dismutase designated isoenzyme I, II and III. The two cytosolic superoxide dismutases (I and II) were purified to homogeneity by ammonium sulphate fractionation, ion exchange chromatography on diethylaminoethyl cellulose, gel filtration and preparative polyacrylamide.gel electrophoresis. The molecular weights of isoenzyme I and isoenzyme II were determined to be 33,000 and 31,600 respectively. The subunit molecular weight was approximately 16,000 indicating that the isoenzymes contained two identical subunits. The ultra-violet absorption spectra revealed a maximum at 258–264 nm for the two isoenzymes. Superoxide dismutase I and II were inhibited to different extents by metal chelators. Isoenzyme I was more sensitive to inhibition by cyanide and azide, while isoenzyme II was more susceptible to inhibition by diethyldithiocarbamate ando-phenanthroline. Both the isoenzymes exhibited similar denaturation profiles with heat, guanidinium chloride and urea. The denaturation with urea and guanidinium chloride was reversible. The two copper-zinc enzymes were more stable towards thermal inactivation compared to manganese and iron superoxide dismutases from other sources. The results indicate that the two isoenzymes differ from each other only with respect to charge and sensitivity towards metal chelators.     

Cell density dependent regulation of phenylalanine hydroxylase activity in hepatoma cells : Evidence for both an active and inactive enzyme form

The cell density dependent regulation of phenylalanine hydroxylase activity in Reuber hepatoma (H4) cells growing in monolayer culture has been examined in detail. We found that 48 h or more after subculture phenylalanine hydroxylase activity in the cells is an exponential function of cell density (cells/cm²). No discontinuity in the relationship is seen with the formation of a confluent monolayer.A rapid loss or a rapid gain in enzyme activity in the cells is observed after diluting or concentrating the cell cultures. The two processes appear qualitatively different. The loss in activity is a first order process which starts at the time of subculture with the rate of loss dependent on the density of subculture. The gain in activity begins 6–8 h after subculture to a higher density; it can be blocked by cycloheximide and has a maximum rate of increase that is about 10% of the maximum rate of loss of activity.Using immunochemical procedures, we found the same amount of phenylalanine hydroxylase associated antigen in Reuber cells from low density as from high density cultures, over a range of phenylalanine hydroxylase specific activities from 0.2 to 4.2. After concentrating cells to a higher density, no increase in enzyme antigen was observed, despite a several-fold increase in enzyme activity and a requirement for protein synthesis during the process. These observations imply the presence of an active and inactive phenylalanine hydroxylase with the relative amounts of each determined by the cell density. The effects of db-cAMP are discussed. Evidence is presented here that the hydrocortisone stimulation of phenylalanine hydroxylase activity works through a different mechanism than the cell density dependent process.     

Isolation and sequence of a cDNA clone which contains the complete coding region of rat phenylalanine hydroxylase. Structural homology with tyrosine hydroxylase, glucocorticoid regulation, and use of alternate polyadenylation sites

Screening of a rat liver cDNA expression library constructed in the vector lambda gt11 with an affinity purified antiserum to rat phenylalanine hydroxylase has resulted in the isolation of two clones which contain the complete coding region (1362 base pairs) of phenylalanine hydroxylase and the entire 3'-untranslated region (562 base pairs). From the nucleotide sequence we deduced the amino acid sequence of the enzyme. The molecular weight is 51,632 (452 amino acids). The rat enzyme is highly homologous to human phenylalanine hydroxylase. The two proteins differ in only 36 amino acids (92% homology), many of which are conservative changes. A dot matrix computer program was used to analyze regions of homology with the amino acid sequence of rat tyrosine hydroxylase. Considerable homology was detected from amino acid 140 in the rat enzyme to the C terminus, but little or no homology was apparent in the N-terminal region. The cDNA clone was used to determine the levels of phenylalanine hydroxylase mRNA in rat tissues using RNA blot hybridization. Two mRNA species were detected, with approximate lengths of 2,000 and 2,400 nucleotides, which appear to derive from use of alternate polyadenylation signals. No difference in mRNA size was found in rats which have different phenylalanine hydroxylase alleles. The kidney was found to contain about 10% of the mRNA found in the liver, and no phenylalanine hydroxylase mRNA was detected in rat brain. Reuber H4 hepatoma cells were also analyzed for phenylalanine hydroxylase mRNA. The parental cells contained mRNA species of the same sizes as in rat liver. Incubation in 10(-6) M hydrocortisone for 24 h resulted in an 18-fold increase in the mRNA level. Mutant hepatoma cells which express very little phenylalanine hydroxylase contained less than 5% of the parental mRNA, but the gene still responded to hydrocortisone.     

Hydrocortisone induction of phenylalanine hydroxylase isozymes in cultured hepatoma cells.

The hydrocortisone stimulation of phenylalanine hydroxylase activity in Reuber H4 hepatoma cells is shown to be associated with an alteration in phenylalanine hydroxylase isozyme composition. Three forms of phenylalanine hydroxylase were identified in H4 cells which have been treated with hydrocortisone; however, only one of these forms appears to be present prior to glucocorticoid treatment. The relative amounts, as well as the total amount, of the three forms and their chromatographic behavior on hydroxylapatite are nearly identical to the three phenylalanine hydroxylase isozymes found in adult rat liver. The hydroxylase isozyme composition in 2 day old rats is similar to that found in adult rats and in H4 cells treated with hydrocortisone.     

The regulation of mitochondrial-bound hexokinases in the liver

A functional coupling between bound hexokinase and the inner mitochondrial compartment has been shown. It is based structurally on the binding of hexokinase to a pore protein which is present in zones of contact between the two boundary membranes. The latter was observed by electron microscopic localization of antiporin and hexokinase at the mitochondrial surface. The four isoenzymes present in liver differ considerably in their activity after binding to the mitochondrial surface. This was found by binding studies using the four isoenzymes isolated from the supernatant. Isoenzyme IV did not bind at all. Isoenzymes I-III did bind and became activated: I, 5.9-fold; II, 39-fold; and III, 1.3-fold. These results suggest that the in vivo activity of hexokinase in the mitochondrial fraction is much larger than so far observed. Furthermore the binding of isoenzymes was differently affected by metabolites. Glucose-6-phosphate exclusively desorbed isoenzyme I from the mitochondrial membrane whereas free fatty acids predominantly liberated isoenzymes II and III. A reciprocal change of the levels of free fatty acids and glucose 6-phosphate in livers of starved rats therefore, can explain why exclusively mitochondrial-bound isoenzymes II and III decreased 10-fold while at the same time isoenzyme I increased.     

Phenylalanine hydroxylase in melanoma cells.

A pigmented subclone of Cloudman S91 melanoma cells, PS1-wild type, can grow in medium lacking tyrosine. This ability is conferred by phenylalanine hydroxylase activity, and not by tryptophan hydroxylase, tyrosine hydroxylase or tyrosinase activities, although the latter activity is also present in these cells. Conversion of phenylalanine to tyrosine was measured in living cells by chromatographic identification of the metabolites of [14C]phenylalanine and in cell extracts using a sensitive assay for phenylalanine hydroxylase. Phenylalanine hydroxylase activity in melanoma cell extracts was identified by its inhibition with p-chlorophenylalanine and not with 6-fluorotryptophan, 3-iodotyrosine, phenylthiourea, tyrosine or tryptophan; and by adsorption with antiserum prepared against purified rat liver phenylalanine hydroxylase, and migration of immunoprecipitable activity with authentic phenylalanine hydroxylase subunits in sodium dodecyl sulfate-polyacrylamide gel electrophoresis.     

The isolation and properties of phenylalanine hydroxylase from rat liver

Phenylalanine hydroxylase was prepared from rat liver and purified 200-fold to about 90% purity. All the enzymic activity of the liver appeared in a single protein of mol.wt. approx. 110000, but omission of dithiothreitol and of a preliminary filtration step to remove lipids resulted in partial conversion into a second enzymically active protein of mol.wt. approx. 250000. The K(m) and V(max.) values of the enzyme for phenylalanine, p-fluorophenylalanine and dimethyltetrahydropterin were measured; p-chlorophenylalanine inhibited the enzyme by competing with phenylalanine. Disc gel electrophoresis at pH7.2 showed a single protein band containing all the enzymic activity, but at pH8.7 the enzyme dissociated into two inactive fragments of similar but not identical molecular weight. The molecule of phenylalanine hydroxylase contained two atoms of iron, one atom of copper and one molecule of FAD; molybdenum was absent. Treatment with chelating agents showed that both non-haem iron and copper were necessary for enzymic activity. The molecule contained five thiol groups, and thiol-binding reagents inhibited the enzyme. Catalase or peroxidase enhanced enzymic activity fivefold; it is postulated that catalase (or other peroxidase) plays a part in the hydroxylation reaction independent of the protection by catalase of enzyme and cofactor from inactivation by a hydroperoxide.     

Expression of liver-specific member of the 3 beta-hydroxysteroid dehydrogenase family, an isoform possessing an almost exclusive 3-ketosteroid reductase activity.

We have recently characterized two types of rat 3 beta-hydroxysteroid dehydrogenase/delta 5-delta 4 isomerase (3 beta-HSD) isoenzymes expressed in adrenals and gonads. In addition, we have cloned a third type of cDNA encoding a predicted type III 3 beta-HSD protein specifically expressed in the male rat liver which shares 80% similarity with the two other isoenzymes. Transient expression in human HeLa cells of the cDNAs reveals that the type III 3 beta-HSD protein does not display oxidative activity for the classical substrates of 3 beta-HSD, in contrast to the type I 3 beta-HSD isoenzyme. However, in the presence of NADH, type III isoenzyme, in common with the type I isoform, converts 5 alpha-androstane-3,17-dione (A-dione) and 5 alpha-dihydrotestosterone (DHT) to the corresponding 3 beta-hydroxysteroids. In fact, the type I and the type III isoenzymes have the same affinity for DHT with Km values of 5.05 and 6.16 microM, respectively. When NADPH is used as cofactor, the affinity for DHT of the type III isoform becomes higher than that of the type I isoform with Km values of 0.12 and 1.18 microM, respectively. The type III isoform is thus a 3-ketoreductase using NADPH as preferred cofactor which is responsible for the conversion of 3-keto-saturated steroids such as DHT and A-dione into less active steroids.