Interaction of prostaglandins with adrenal microsomal cytochrome P-450 in the guinea pig

Studies were carried out to investigate the effects of prostaglandins (PG) $\text{in vitro}$ on adrenal microsomal steroid and drug metabolism in the guinea pig. The addition of PGE₁, PGE₂, PGA₁, PGF_1α or PGF_2α to isolated adrenal microsomes produced typical type I difference spectra. The sizes of the spectra (ΔA_385–420) produced by prostaglandins were smaller than those produced by various steroids including progesterone, 17-hydroxyprogesterone and 11β-hydroxyprogesterone. However, the affinities of prostaglandins and steroids for adrenal microsomal cytochrome P-450, as estimated by the spectral dissociation constants, were similar. Prior addition of prostaglandins to isolated adrenal microsomes did not affect steroid binding to cytochrome P-450 or the rate of steroid 21-hydroxylation. In contrast, prostaglandins inhibited adrenal metabolism of ethylmorphine and diminished the magnitude of the ethylmorphine-induced spectral change in adrenal microsomes. The results indicate that prostaglandins inhibit adrenal drug metabolism by interfering with substrate binding to cytochrome P-450. Since 21-hydroxylation was unaffected by PG, different cytochrome P-450 moieties are probably involved in adrenal drug and steroid metabolism.     

Interaction of prostaglandins with adrenal microsomal cytochrome P-450 in the guinea pig.

Studies were carried out to investigate the effects of prostaglandins (PG) in vitro on adrenal microsomal steroid and drug metabolism in the guinea pig. The addition of PGE1, PGE2, PGA1, PGF1 alpha or PGF2 alpha to isolated adrenal microsomes produced typical type I difference spectra. The sizes of the spectra (delta A385-420) produced by prostaglandins were smaller than those produced by various steroids including progesterone, 17-hydroxyprogesterone and 11 beta-hydroxyprogesterone. However, the affinities of prostaglandins and steroids for adrenal microsomal cytochrome P-450, as estimated by the spectral dissociation constants, were similar. Prior addition of prostaglandins to isolated adrenal microsomes did not affect steroid binding to cytochrome P-450 or the rate of steroid 21-hydroxylation. In contrast, prostaglandins inhibited adrenal metabolism of ethylmorphine and diminished the magnitude of the ethylmorphine-induced spectral change in adrenal microsomes. The results indicate that prostaglandins inhibit adrenal drug metabolism by interfering with substrate binding to cytochrome P-450. Since 21-hydroxylation was unaffected by PG, different cytochrome P-450 moieties are probably involved in adrenal drug and steroid metabolism.     

The involvement of cytochrome P-450 in hepatic microsomal steroid hydroxylation reactions supported by sodium periodate, sodium chlorite, and organic hydroperoxides.

The mechanism of steroid hydroxylation in rat liver microsomes has been investigated by employing NaIO4, NaClO2, and various organic hydroperoxides as hydroxylating agents and comparing the reaction rates and steroid products formed with those of the NADPH-dependent reaction. Androstenedione, testosterone, progesterone, and 17beta-estradiol were found to act as good substrates. NaIO4 was by far the most effective hydroxylating agent followed by cumene hydroperoxide, NADPH, NaClO2, pregnenolone 17alpha-hydroperoxide, tert-butyl hydroperoxide, and linoleic acid hydroperoxide. Androstenedione was chosen as the model substrate for inducer and inhibitor studies. The steroid was converted to its respective 6beta-, 7alpha, 15-, and 16alpha-hydroxy derivatives when incubated with microsomal fractions fortified with hydroxylating agent. Evidence for cytochrome P-450 involvement in androstenedione hydroxylation included a marked inhibition by substrates and modifiers of cytochrome P-450 and by reagents which convert cytochrome P-450 to cytochrome P-420. The ratios of the steroid products varied according to the type of hydroxylating agent used and were also modified by in vivo phenobarbital pretreatment. It was suggested that multiple forms of cytochrome P-450 exhibiting different affinities for hydroxylating agent are responsible for these different ratios. Horse-radish peroxidase, catalase, and metmyoglobin could not catalyze androstenedione hydroxylation. Addition of NaIO4, NaClO2, cumene hydroperoxide and other organic hydroperoxides to microsomal suspensions resulted in the appearance of a transient spectral change in the difference spectrum characterized by a peak at about 440 nm and a trough at 420 nm. The efficiency of these oxidizing agents in promoting steroid hydroxylation in microsomes appeared to be related to their effectiveness in eliciting the spectral complex. Electron donors, substrates, and modifiers of cytochrome P-450 greatly diminished the magnitude of the spectral change. It is proposed that NaIO4, NaClO2, and organic hydroperoxides promote steroid hydroxylation by forming a transient ferryl ion (compound I) of cytochrome P-450 which may be the common intermediate hydroxylating species involved in hydroxylations catalyzed by cytochrome P-450.     

Uncoupling of oxygen activation from hydroxylation in the steroid C-21 hydroxylase of bovine adrenocortical microsomes

Androst-4-ene-3,17-dione, although not hydroxylated by the C-21 hydroxylase, induces Type I spectral change in cytochrome P-450 and stimulates NADPH oxidation and oxygen consumption. The androstenedione-dependent oxygen activation results in reduction of oxygen to water without producing a free peroxide intermediate as evidenced by the ratio of NADPH oxidized to O₂ consumed being equal to 2 in the presence of this steroid.     

Cytochrome P450 and steroid 21-hydroxylation in microsomes from beef adrenal cortex

Cytochrome P450 in beef adrenal cortex microsomal preparations reacted with progesterone and with 17-hydroxyprogesterone at pH 7.4 to produce Type I spectral changes. The magnitude of the spectral shift produced by addition of progesterone or 17-hydroxyprogesterone was related to the concentration of cytochrome P450 (over P450 concentration range of 0.1 to 0.3 μM). Prior saturation of cytochrome P450 with 17-hydroxyprogesterone prevented further spectral shift with the addition of progesterone. On the other hand, saturation of cytochrome P450 with progesterone decreases the expected shift with 17-hydroxyprogesterone by more than 50% but did not prevent the shift. The difference spectra were diminished by more than 50% at pH 9.0.The addition of NADPH resulted in loss of the spectral shifts and production of 21-hydroxylated products, predominantly DOC and 11-deoxycortisol. These reactions were not inhibited by their specific products. The rate of 21-hydroxylation was linearly related to microsomal protein (and microsomal P450) concentration. The 21-hydroxylation of progesterone was competitively inhibited by 17-hydroxyprogesterone; inhibition of the 21-hydroxylation of 17-hydroxyprogesterone by progesterone was not demonstrated.     

Participation of cytochrome P-450 in the steroid 17alpha-hydroxylase of testis microsomes.

The effect of metyrapone on the activity of the steroid 17alpha-hydroxylase from rat testis was evaluated. A competitive pattern of inhibition was observed after analysis of data using a least mean squares computer analysis. The substrate for the hydroxylase induced a Type I difference spectrum in an active suspension of Triton treated microsomes. The magnitude of this spectral change was dependent on steroid concentration and was diminished by metyrapone. The effect of metyrapone was abolished at infinite steroid concentration. These results confirm the participation of cytochrome P-450 as a reactant in the 17alpha-hydroxylase reaction.     

Effects of cadmium in vitro on microsomal steroid metabolism in the inner and outer zones of the guinea pig adrenal cortex

Studies were carried out to evaluate the effects of cadmium in vitro on microsomal steroid metabolism in the inner (zona reticularis) and outer (zona fasciculata and zona glomerulosa) zones of the guinea pig adrenal cortex. Microsomes from the inner zone have greater 21-hydroxylase than 17α-hydroxylase activity, resulting in the conversion of progesterone primarily to 11-deoxycorticosterone and of 17α-hydroxy progesterone principally to its 21-hydroxylated metabolite, 11-deoxycortisol. Microsomes from the outer zones, by contrast, have far greater 17α-hydroxylase and C_17,20-lyase activities than 21-hydroxylase activity. As a result, progesterone is converted primarily to its 17-hydroxylated metabolite, 17α-hydroxyprogesterone; and 17α-hydroxyprogesterone is converted principally to δ⁴-androstenedione, with only small amounts of 21-hydroxylated metabolites being produced. Addition of cadmium to incubations with inner zone microsomes causes concentration-dependent decreases in 21-hydroxylation and increases in 17α-hydroxylase and C_17,20-lyase activities, resulting in a pattern of steroid metabolism similar to that in normal outer zone microsomes. Cadmium similarly decreases 21-hydroxylation by outer zone microsomes but has no effect on the formation of 17-hydroxylated metabolites or on androgen (Δ⁴-androstenedione) production. In neither inner nor outer zone microsomes did cadmium affect cytochrome P-450 concentrations, steroid interactions with cytochrome(s) P-450, or NADPH–cytochrome P-450 reductase activities. The results indicate that cadmium produces both quantitative and qualitative changes in adrenal microsomal steroid metabolism and that the nature of the changes differs in the inner and outer adrenocortical zones. In inner zone microsomes, there appears to be a reciprocal relationship between 21-hydroxylase and 17α-hydroxylase/C_17,20-lyase activities which may influence the physiological function(s) of that zone.     

Effect of a single oral dose of methanol, ethanol and propan-2-ol on the hepatic microsomal metabolism of foreign compounds in the rat.

Methanol and ethanol administered to rats as a single oral dose increased aniline hydroxylation by the hepatic microsomal fraction by a maximum of 169 and 66% respectively, whereas aminopyrine demethylation was inhibited by 51 and 61%. The concentration of microsomal cytochrome P-450, and the activities of NADPH-cytochrome c reductase and NADPH-cytochrome P-450 reductase were unchanged. Propan-2-ol, administered as a single oral dose, increased microsomal aniline hydroxylation by 165% and increased aminopyrine demethylation by 83%. The concentration of cytochrome P-450 was unchanged whereas NADPH-cytochrome c reductase and NADPH-cytochrome P-450 reductase were both increased by 38%. Methanol, ethanol and propan-2-ol administration resulted in a decreased type I spectral change but had no effect on the reverse type I spectral change. Methanol administration decreased the type II spectral change whereas ethanol and propan-2-ol had no effect. Cycloheximide blocked the increases in aniline hydroxylation and aminopyrine demethylation but could not completely prevent the decreases in aminopyrine demethylation. The increases in aniline hydroxylation were due to an increase in V, but Km was unchanged. The ability of acetone to enhance and compound SKF 525A to inhibit microsomal aniline hydroxylation was decreased by the administration of all three alcohols. The decrease in the metabolism of aminopyrine may result from a decrease in the binding to the type I site with a consequent failure of aminopyrine to stimulate the reduction of cytochrome P-450. Methanol administration may lead to an increase in aniline hydroxylation because of a failure of aniline to inhibit cytochrome P-450 reduction.     

Spectroscopic evidence of interaction between 2-allyl-2-isopropylacetamide and cytochrome P-450 of rat liver microsomes

2-allyl-2-isopropylacetamide (AIA) causes marked induction of heme synthesis in rats and other species, degrades cytochrome P-450 in the presence of NADPH and causes experimental porphyria. Using difference spectroscopy we sought evidence of an interaction between AIA and P-450 in microsomes prepared from rat liver. AIA alone caused small and variable changes in the spectral properties of liver microsomes but markedly inhibited the Type I spectral change due to hexobarbitone. Phenobarbitone exhibited behaviour qualitatively similar to AIA. It is concluded that AIA binds to cytochrome P-450 without much altering its spectral properties but in such a way as to prevent the change induced by the Type I substrate hexobarbitone.     

Structural analysis of cloned cDNA for mRNA of microsomal cytochrome P-450(C21) which catalyzes steroid 21-hydroxylation in bovine adrenal cortex

We have isolated cDNA clones of the mRNA for cytochrome P-450 that catalyzes the steroid C-21 hydroxylation (P-450(C21)), which specifically catalyzes 21-hydroxylation of steroids in the microsomes of bovine adrenal cortex by using synthetic oligonucleotides as probes. Sequence determination of the cloned cDNA showed that it contains 2157 nucleotides and a poly(A) chain and that a single open reading frame of 1488 nucleotides codes for a polypeptide of 496 amino acids with a molecular weight of 56,113. The deduced amino acid composition is in agreement with that determined by direct amino acid analysis of purified P-450(C21) and the predicted primary structure contained amino acid sequences of N-terminal region and two internal tryptic fragments of the protein so far analyzed. Comparing the amino acid sequence with those of other forms of P-450 reveals that a conserved amino acid sequence containing a putative heme-binding cysteine is present in the equivalent position, proximate to the COOH terminus of the molecules and that P-450(C21) is phylogenically situated in an intermediate position between steroidogenic mitochondrial cytochrome P-450 which catalyzes the side-chain cleavage of cholesterol (P-450(SCC)) and drug-metabolizing microsomal P-450s. However, the amino acid sequence of P-450(C21) is much closer to that of drug-metabolizing P-450s than to that of P-450(SCC).     

Studies on the microsomal electron-transport system of anaerobically grown yeast. III. Spectral characterization of cytochrome P-450.

A carbon monoxide-binding pigment which shows an absorption peak at about 450 nm in the reduced carbon monoxide difference spectrum was purified from the microsomal fraction of yeast grown anaerobically. The spectral characteristics of the pigment were practically identical with those of cytochrome P-450 of hepatic microsomes, especially from polycyclic hydrocarbon-induced animals. The pigment was denatured to P-420, and bound with ethyl isocyanide in the reduced state. Although Type I spectral change was not evident, the pigment showed Type II and modified Type II spectral changes upon binding with some organic compounds, as in the case of hepatic cytochrome P-450. These observations clearly indicate that the carbon monoxide-binding pigment of yeast microsomes may be designated as cytochrome P-450 of yeast.     

Studies on the substrate-induced spectral change of cytochrome P-450 in liver microsomes.

The spectral changes of cytochrome P-450 caused by the addition of small molecules to liver microsomes were investigated precisely and the following conclusions were reached. 1. The Type I spectral change was entirely due to the interaction of the cytochrome with a hydrocarbon residue in a ligand. To induce the modified Type II spectral change, the presence of a hydroxyl group in a ligand was required. Compounds which contain a basic amino group induced the Type II spectral change. 2. The Type I spectral change was caused by the interaction of a ligand with the 419-nm form of cytochrome P-450, with its concomitant conversion to the 394-nm form. Whereas, compounds inducing modified Type II spectral change interacted with the 394nm form of the cytochrome. In this case, however, the 394-nm form was not converted back to the 419-nm form but was converted to a new state showing an absorption peak at 416 nm. The Type II spectral change-inducing interaction of a ligand with the cytochrome could occur with all forms of the cytochrome. 3. Both Type II and modified Type II compounds bound to the cytochrome at heme iron, and converted the cytochrome into modified ferrihemochromes. On the other hand, the Type I interaction occurred ina protein moiety of the cytochrome, and probably caused a conformational change of the cytochrome accompanied either by weakening of the internal ligand interaction or by displacement of the ligand with another one having a weaker field at the heme iron. 4. Type I and each of other two types of binding of compounds with cytochrome P-450 could occur simultaneously.     

Subterminal hydroxylation of fatty acids by a cytochrome P-450-dependent enzyme system from a fungus, Fusarium oxysporum

The cell-free extract of a cytochrome P-450-producing fungus, Fusarium oxysporum, was found to catalyze the hydroxylation of fatty acids. Three product isomers were formed from a single fatty acid. The products from lauric acid were identified by mass-spectrometry as 9-, 10-, and 11-hydroxydodecanoic acids, and those from palmitic acid as 13-, 14-, and 15-hydroxyhexadecanoic acids. The ratio of the isomers formed was 50 : 36 : 14 in the case of laurate hydroxylation, and 37 : 47 : 16 in the case of palmitate. The reaction was dependent on both NADPH (or NADH) and molecular oxygen,and was strongly inhibited by carbon monoxide, menadione, or the antibody to purified Fusarium P-450. Further, lauric acid induced a type I spectral change in purified Fusarium P-450. Further, lauric acid induced a type I spectral change in purified Fusarium P-450 with an apparent Kd of 0.3 mM. The hydroxylase activity together with cytochrome P-450 could be detected in both the soluble and microsome fractions, and the activity was almost proportional to the amount of cytochrome P-450 reducible with NADPH. It can be concluded from these results that Fusarium P-450 reducible with NADPH. It can be concluded from these results that Fusarium P-450 is involved in the (omega-1)-, (omega-2)-, and (omega-3)-hydroxylation of fatty acids catalyzed by the cell-free extract of the fungus.     

Collagenolytic activity of rabbit V2-carcinoma growing at multiple sites.

Interaction between lanosterol and cytochrome P-450 purified from microsomes of anaerobically-grown Saccharomyces cerevisiae was studied. Lanosterol (4,4,14α-trimethyl-5α-cholesta-8,24-dien-3β-ol) stimulated the oxidation of NADPH by molecular oxygen in the presence of cytochrome P-450 and NADPH-cytochrome P-450 reductase both purified from S. cerevisiae microsomes. Lanosterol stimulated the reduction of cytochrome P-450 by NADPH with the cytochrome P-450 reductase, and induced Type I spectral change of cytochrome P-450. These observations suggest that lanosterol interacts to the substrate region of cytochrome P-450 of S. cerevisiae. Based on these facts, possible role of cytochrome P-450 in lanosterol metabolism in yeast cell is discussed.     

Structure-activity relationships in the in vitro modulation of rat hepatic microsomal androst-4-ene-3,17-dione hydroxylase activities by derivatives of 5 alpha- and 5 beta-androstane

The relationships between structure and inhibitory potency toward microsomal cytochrome P-450 (P-450)-mediated androst-4-ene-3,17-dione hydroxylase activities were investigated in rat liver with a series of 5 alpha- and 5 beta-androstane derivatives. 5 beta-Reduced steroids (containing a cis-A/B ring junction) were more potent inhibitors than the 5 alpha-reduced epimers (containing a trans-A/B ring junction) except in the case of the 17 beta-hydroxy-substituted derivatives. The most effective inhibitor was 5 beta-androstane-3 beta-ol which exhibited I50 values of 7 and 27 microM against androstenedione 16 alpha- and 6 beta-hydroxylase activities, which are catalysed by P-450 IIC11 and IIIA2, respectively. In general, these two pathways of steroid hydroxylation were more susceptible to inhibition than the 7 alpha- and 16 beta-hydroxylase pathways. The 7 alpha-hydroxylase enzyme (P-450 IIA1) was only inhibited by 5 beta-reduced steroids that contained an oxygenated function at C17. All of the test compounds elicited type I spectral binding interactions with P-450 in oxidised microsomes. The most effective steroid inhibitors generally exhibited the greatest capacity to interact with P-450. Additional studies with one of the more potent compounds, 5 beta-androstane-3 beta-ol-17-one, revealed that the inhibition kinetics were competitive and that preincubation of the inhibitor with NADPH-supplemented microsomes prior to substrate (androstenedione) addition decreased the extent of inhibition observed. These findings are consistent with the assertion that the inhibition of hepatic steroid hydroxylases by 5 beta-androstanes involves an effective competitive interaction with the steroid substrate at the P-450 active site. Since the relative overproduction of 5 beta-reduced metabolites of certain androgens has been reported in clinical conditions, such as androgen insensitivity, it now appears important to investigate the hepatic drug oxidation capacity of patients with hormonal abnormalities.     

Absorbance spectral change of the cytochrome P-450S21-phenylisocyanide complex upon binding of reduced NADPH-cytochrome-P-450 reductase.

Reduction of cytochrome P-450S21 (SF) (SF, substrate-free; purified from bovine adrenocortical microsomes) with sodium dithionite (Na2S2O4) in the presence of phenylisocyanide produced a ferrous cytochrome P-450S21 (SF)-phenylisocyanide complex with Soret absorbance maxima at 429 and 456 nm. On the other hand, when a preformed ferric cytochrome P-450S21 (SF)-NADPH-cytochrome-P-450 reductase (Fp2) complex was reduced chemically or enzymatically under the same conditions, the absorbance spectrum of the ferrous cytochrome P-450S21 (SF)-phenylisocyanide complex changed drastically, as characterized by an increase in absorbance intensity at 429 nm and a decrease at 456 nm. Similar spectral changes were observed by addition of reduced Fp2 to the preformed ferrous cytochrome P-450S21 (SF)-phenylisocyanide complex. Experiments to reduce a ferric cytochrome P-450S21 (SF)-phenylisocyanide complex with sodium dithionite in the presence of various amounts of Fp2 showed that; (1), the spectral change reached maxima for both absorption increase at 429 nm and decrease at 456 nm when cytochrome P-450S21 and Fp2 were previously mixed at the cytochrome P-450S21:Fp2 ratio of 1:5; (2), the spectral change was suppressed in 300 mM potassium phosphate buffer (pH 7.4). These results suggest that the absorbance spectral change is due to a conformational change around the heme moiety induced by association with reduced Fp2.     

The regulation of ovine placental steroid 17 alpha-hydroxylase and aromatase by glucocorticoid

Parturition in the pregnant sheep is preceded by an abrupt alteration in placental steroid metabolism causing a shift from progesterone to estrogen production. This change is believed to be a consequence of the prepartum rise in cortisol in the fetal circulation and involves increases in activities of the enzymes steroid 17 alpha-hydroxylase (cytochrome P-450(17)alpha), steroid C-17,20-lyase, and possibly aromatase. We have investigated the activity levels of aromatase and 17 alpha-hydroxylase in placental microsomes in late pregnancy and dexamethasone-induced labor. Over the gestational period of 118-140 days basal levels of placental aromatase were relatively constant [mean value (+/- SD) of 5.6 +/- 1.6 pmol min-1 mg microsomal protein-1 (n = 10)]. Steroid 17 alpha-hydroxylase activity was undetectable [less than 0.5 pmol min-1 mg microsomal protein-1 (n = 7)]. In six animals in labor induced with infusion of dexamethasone into the fetus, placental aromatase activity had a mean value of 14.0 +/- 2.5 pmol min-1 mg protein-1; placental steroid 17 alpha-hydroxylase, measured in four of the animals, had a mean (+/- SD) activity of 319 +/- 58 pmol min-1 mg microsomal protein-1. Immunoblotting of placental microsomal preparations with specific antibodies to cytochrome P-450(17)alpha and NADPH-cytochrome P-450-reductase indicated that the glucocorticoid-induced activity of 17 alpha-hydroxylase was associated with increased content of cytochrome P-450(17)alpha. Northern blotting with a cDNA probe for cytochrome P-450(17)alpha showed that glucocorticoid increased the levels of mRNA for the enzyme.(ABSTRACT TRUNCATED AT 250 WORDS)     

Biochemical and ultrastructural studies on the interaction of basic proteins with mitochondria: a primary effect on membrane configuration

The cytochrome P-450_K containing monooxygenase system of rat kidney cortex microsomes catalyzes the hydroxylation of various saturated fatty acids of medium chain length to the corresponding ω- and (ω-1)-hydroxy derivatives. The hydroxylation activity, as well as the ratio between the two hydroxylated products, vary with the carbon chain length of the fatty acid. Optimal hydroxylation activity is observed with myristic acid which yields the 13- and 14-hydroxylated products at a ratio of about 1. The ω/(ω-1)-hydroxylation ratio decreases with increasing carbon chain length of the fatty acid. On the other hand, with lauric acid as a substrate the ratio between ω- and (ω-1)-hydroxylation does not change significantly with varying time of incubation or substrate concentration, or incubation in a medium containing D₂O or after induction of enhanced hydroxylation activity by starvation of the animals. Furthermore, 12-hydroxylauric acid and capric acid—which is almost exclusively ω-hydroxylated by rat kidney cortex microsomes—inhibit both 11- and 12-hydroxylation of lauric acid to a similar extent whereas 11-hydroxylauric acid does not seem to inhibit either 11- or 12-hydroxylation.C₁₀-C₁₆ fatty acids produce the type I spectral change upon addition to rat kidney cortex microsomes and seem to interact with similar amounts of the cytochrome P-450_K present in these particles. In agreement with the metabolic studies, 12-hydroxylauric acid interacts with cytochrome P-450_K giving rise to a reverse type I spectral change, whereas 11-hydroxylauric acid does not produce an observable spectral change. Finally, results of binding experiments with a series of derivatives of dodecane suggest that type I binding to cytochrome P-450_K requires, besides a proper chain length, the presence of a carbonyl group together with an electron pair on a neighboring atom at the end of the carbon chain. A chain length of 14 carbon atoms seems to be optimal and it is suggested that this chain length may correspond to the distance between a possible binding site and the catalytic site of cytochrome P-450_K     

The expression of cytochrome P-450 and cytochrome P-450 reductase genes in the simultaneous transformation of corticosteroids and phenanthrene by Cunninghamella elegans

The expression of cytochrome P-450 and cytochrome P-450 reductase (CPR) genes in the conterminous biotransformation of corticosteroids and PAHs was studied in Cunninghamella elegans 1785/21Gp. We had previously used this strain as a microbial eucaryotic model for studying the relationship between mammalian steroid hydroxylation and the metabolization of PAHs. We reported that cytochrome P-450 reductase is involved in the biotransformaton of cortexolone and phenanthrene. RT-PCR and Northern blotting analyses indicated that the cytochrome P-450 and CPR genes appear to be inducible by both steroids and PAHs. The expression of the cytochrome P-450 gene was increased ninefold and the expression of the CPR gene increased 6.4-fold in cultures with cortexolone and/or phenanthrene in comparison with controls. We conclude that the increase in cytochrome P-450 gene expression was accompanied by an increase in cytochrome P-450 enzymatic activity levels.     

A novel method for the preparation of substrate-free cytochrome P-450(11) beta

A new method for the removal of the stabilizing substrate, deoxycorticosterone, from adrenal cytochrome P-450(11) beta, has been developed. Dextran coated charcoal is used for the adsorption of the steroid and the adsorbed steroid is separated from the cytochrome P-450-preparation by low speed centrifugation. The substrate-free enzyme, obtained in this manner, has all the characteristic spectral properties of low-spin cytochrome P-450(11) beta and may be converted to the high-spin form by the addition of deoxycorticosterone. The dextran coated charcoal method has the following advantages over the previously used method of substrate removal. It does not require the addition of the cofactors for cytochrome P-450-dependant hydroxylation of deoxycorticosterone, small amounts of enzyme may be prepared in a short time and the enzyme preparation is not diluted to any great extent during the process.