Inducibility of Cytochrome P-450 and of NADPH-cytochrome C reductase in progesterone treated filamentous fungi Rhizopus nigricans and Rhizopus arrhizus

Biotransformation of Androstenedione by Filamentous Fungi Isolated from Cultural Heritage Sites in the State Tretyakov Gallery

Simple Summary

Microorganisms are able to grow on substrates of the most diverse nature. One of the most practical habitats, in terms of cultural heritage conservation, is fine art objects such as tempera or oil paintings on canvas. Since tempera paints are produced on the basis of egg yolk, which is one of the richest sources of cholesterol in nature (up to 2% of dry weight), and in the process of aging of tempera materials, changes in cholesterol do not affect the core structure of the steroid nucleus, the group of fungi that we have isolated are tempera painting destructors is seen as a promising object for screening for their possible steroid-transforming activities. In this regard, the purpose of our work was to determine the ability to transform pharmaceutically significant steroids with dominant fungi-destructors of tempera paintings, previously isolated in the State Tretyakov Gallery. Consequently, we have demonstrated for the first time that fungi-destructors of tempera paintings have steroid-transforming activity and are promising microorganisms for screening for biotechnologically significant transformations of steroids with further industrial use.

Abstract

The transformation of steroids by microorganisms is widely used in medical biotechnology. A huge group of filamentous fungi is one of the most promising taxa for screening new biocatalytic reactions in order to obtain pharmaceutically significant steroids. In this work, we screened 10 filamentous fungi-destructors of egg tempera for the ability to biotransform androst-4-en-3,17-dione (AD) during cultivation in a liquid nutrient medium or in a buffer solution. These taxonomically unrelated strains, belonging to the classes Eurotiomycetes, Dothideomycetes and Sordariomycetes, are dominant representatives of the microbiome from halls where works of tempera painting are stored in the State Tretyakov Gallery (STG, Moscow, Russia). Since the binder of tempera paints, egg yolk, contains about 2% cholesterol, these degrading fungi appear to be a promising group for screening for steroid converting activity. It turned out that all the studied fungi-destructors are able to transform AD. Some strains showed transformation efficiency close to the industrial strain Curvularia lunata RNCIM F-981. In total, 33 steroids formed during the transformation of AD were characterized, for 19 of them the structure was established by gas chromatography/mass spectrometry analysis. In this work, we have shown for the first time that fungi-destructors of tempera paintings can efficiently transform steroids.

Co-production of 11α-hydroxyprogesterone and ethanol using recombinant yeast expressing fungal steroid hydroxylases

BACKGROUND

Bioethanol production from sustainable sources of biomass that limit effect on food production are needed and in a biorefinery approach co-products are desirable, obtained from both the plant material and from the microbial biomass. Fungal biotransformation of steroids was among the first industrial biotransformations allowing corticosteroid production. In this work, the potential of yeast to produce intermediates needed in corticosteroid production is demonstrated at laboratory scale following bioethanol production from perennial ryegrass juice.

RESULTS

Genes encoding the 11α-steroid hydroxylase enzymes from Aspergillus ochraceus (11α-SH^Aoch) and Rhizopus oryzae (CYP509C12) transformed into Saccharomyces cerevisiae for heterologous constitutive expression in p425TEF. Both recombinant yeasts (AH22:p11α-SH^Aoch and AH22:p509C12) exhibited efficient progesterone bioconversion (on glucose minimal medial containing 300 µM progesterone) producing either 11α-hydroxyprogesterone as the sole metabolite (AH22:p11α-SH^Aoch) or a 7:1 mixture of 11α-hydroxyprogesterone and 6β-hydroxyprogesterone (AH22:p509C12). Ethanol yields for AH22:p11α-SH^Aoch and AH22:p509C12 were comparable resulting in ≥75% conversion of glucose to alcohol. Co-production of bioethanol together with efficient production of the 11-OH intermediate for corticosteroid manufacture was then demonstrated using perennial ryegrass juice. Integration of the 11α-SH^Aoch gene into the yeast genome (AH22:11α-SHAoch+K) resulted in a 36% reduction in yield of 11α-hydroxyprogesterone to 174 µmol/L using 300 µM progesterone. However, increasing progesterone concentration to 955 µM and optimizing growth conditions increased 11α-hydroxyprogesterone production to 592 µmol/L product formed.

CONCLUSIONS

The progesterone 11α-steroid hydroxylases from A. ochraceus and R. oryzae, both monooxygenase enzymes of the cytochrome P450 superfamily, have been functionally expressed in S. cerevisiae. It appears that these activities in fungi are not associated with a conserved family of cytochromes P450. The activity of the A. ochraceous enzyme was important as the specificity of the biotransformation yielded just the 11-OH product needed for corticosteroid production. The data presented demonstrate how recombinant yeast could find application in rural biorefinery processes where co-production of value-added products (11α-hydroxyprogesterone and ethanol) from novel feedstocks is an emergent and attractive possibility.

Cloning and identification of a novel steroid 11α-hydroxylase gene from Absidia coerulea

Steroid 11-hydroxylation by filamentous fungi is a major route for industrial scale production of key intermediates in the synthesis of steroid drugs. Although it is well established that enzymes involved in fungal hydroxylation of steroids are cytochrome P450s (CYP), few fungal steroid hydroxylase genes have been identified. In this study, we identified a novel 11α-hydroxylase gene CYP5311B1 from Absidia coerulea AS3.65 by a combination of transcriptome sequencing, real-time qRT-PCR and heterologous expression in Pichia pastoris. The full-length open reading frame (ORF) of CYP5311B1 is predicted to encode a CYP protein of 527 amino acids whose expression in Pichia cells was confirmed by western blot. In addition, the major hydroxylation product was characterized by HPLC and 2D NMR. CYP5311B1 was highly induced by steroid substrate at the transcriptional level. The cloning and identification of an 11α-hydroxylase gene from A. coerulea should aid in a better understanding of the structural basis underlying regio- and stereoselectivity, and substrate specificity of fungal steroid 11α-hydroxylases, thus facilitating the engineering of more efficient steroid hydroxylases for industrial applications.

Identification and partial characterization of Rhizopus nigricans Gβ proteins and their expression in the presence of progesterone

The mammalian steroid hormone progesterone actuates a signalling pathway in the zygomycete Rhizopus nigricans which includes heterotrimeric G proteins. To investigate the possibility that the Gβ subunit of these proteins is involved in the signalling, a cDNA library from R. nigricans exposed to progesterone was prepared and a sequence coding for a Gβ subunit was searched for. Using degenerate primers, two sequences, RnGPB1 and RnGPB2, were identified that exhibited a high degree of identity with those for Gβ from other filamentous fungi, but not from yeast. The presence of more than one Gβ subunit is very rare among the fungi, and it has been to date reported only for Rhizopus oryzae. We have shown that progesterone increases the expression of RnGPB1, but has no influence on the expression of RnGPB2. Therefore, our studies imply the involvement of Gβ subunit 1 in the response of R. nigricans to progesterone. Moreover, the Gβ subunit is subjected to endogenous ADP-ribosylation in the presence of NAD, which could be important in some, as yet unknown, cell process. Article from a special issue on steroids and microorganisms.

Possible involvement of G-proteins and cAMP in the induction of progesterone hydroxylating enzyme system in the vascular wilt fungus Fusarium oxysporum

Fungi present the ability to hydroxylate steroids. In some filamentous fungi, progesterone induces an enzyme system which converts the compound into a less toxic hydroxylated product. We investigated the progesterone response in the vascular wilt pathogen Fusarium oxysporum, using mass spectrometry and high performance liquid chromatography (HPLC). Progesterone was mainly transformed into 15alpha-hydroxyprogesterone, which was found predominantly in the extracellular medium. The role of two conserved fungal signaling cascades in the induction of the progesterone-transforming enzyme system was studied, using knockout mutants lacking the mitogen-activated protein kinase Fmk1 or the heterotrimeric G-protein beta subunit Fgb1 functioning upstream of the cyclic adenosine monophosphate (cAMP) pathway. No steroid hydroxylation was induced in the Deltafgb1 strain, suggesting a role for the G-protein beta subunit in progesterone signaling. Exogenous cAMP restored the induction of progesterone-transforming activity in the Deltafgb1 strain, suggesting that steroid signaling in F. oxysporum is mediated by the cAMP-PKA pathway.

Studies on Bacillus stearothermophilus. Part IV. Influence of enhancers on biotransformation of testosterone

The impact of chemical enhancers on the biotransformation of testosterone has been exploited. Application of crude cell concentrates to produce Bacillus stearothermophilus-mediated bioconversion of testosterone at 65 degrees C for 72 h has been examined. After incubation, the xenobiotic substrate was added to the concentrated whole cell suspensions. The enhancer molecules were included in the whole cell suspension. The resultant products, after extraction into an organic solvent, were purified by thin layer chromatography and identification was carried out through spectroscopic data. Five steroid metabolites 9,10-seco-4-androstene-3,9,17-trione, 5alpha-androstan-3,6,17-trione, 17beta-hydroxy-5alpha-androstan-3,6-dione, 3beta,17beta-dihydroxyandrost-4-ene-6-one and 17beta-hydroxyandrost-4,6-diene-3-one were identified as biotransformation products of testosterone. A possible biosynthetic route for these bioconversion products is postulated.

Specific interactions of steroids, arylhydrocarbons and flavonoids with progesterone receptors from the cytosol of the fungus Rhizopus nigricans

Rhizopus nigricans (R. nigricans) transforms fungitoxic progesterone into the less toxic 11alpha-hydroxyprogesterone which is then able to exit the mycelia into the surrounding water. Hydroxylation of progesterone is an inducible process in which cytosolic progesterone receptors could be involved. In the present study, we characterised receptors with respect to ligand specificity and to their involvement in progesterone induction of hydroxylase. EC(50) values of different ligands (steroids, xenobiotic arylhydrocarbons and natural flavonoids) were determined by competition studies using 40nM ((3)H)progesterone. C21 and C19 3-oxo-4-ene steroids were good competitors (EC(50) of progesterone 2.3 +/- 0.1 x 10(-7)M, EC(50) of androsten-3,17-dione 24 +/- 2 x 10(-7)M). The presence of hydroxyl groups in steroids significantly decreased the affinity for receptors. The arylhydrocarbons alpha-naphthoflavone and ketoconazole exhibited EC(50) values of 0.3 +/- 0.01 x 10(-7)M and 27 +/- 5 x 10(-7)M, respectively, whereas beta-naphthoflavone and benzo(a)pyrene were not able to displace labelled progesterone completely. The competition curves obtained by natural flavonoids also did not reach the bottom level of non-labelled progesterone, indicating the interaction at some allosteric binding site(s) of progesterone receptors. All ligands were examined for their involvement in progesterone-hydroxylase induction. Steroid agonists induced the enzyme in a dose-dependent manner in accordance with their affinity for receptors, whereas arylhydrocarbons and natural flavonoids did not induce the enzyme. The agonistic action of steroids, together with the antagonistic action of alpha-naphthoflavone, strongly suggests the involvement of progesterone receptors in progesterone signalling resulting in the induction of progesterone-hydroxylase.

The biodiversity of microbial cytochromes P450

The cytochrome P450 (CYP) superfamily of genes and proteins are well known for their involvement in pharmacology and toxicology, but also increasingly for their importance and diversity in microbes. The extent of diversity has only recently become apparent with the emergence of data from whole genome sequencing projects and the coming years will reveal even more information on the diversity in microbial eukaryotes. This review seeks to describe the historical development of these studies and to highlight the importance of the genes and proteins. CYPs are deeply involved in the development of strategies for deterrence and attraction as well as detoxification. As such, there is intense interest in pathways of secondary metabolism that include CYPs in oxidative tailoring of antibiotics, sometimes influencing potency as bioactive compounds. Further to this is interest in CYPs in metabolism of xenobiotics for use as carbon sources for microbial growth and as biotransformation agents or in bioremediation. CYPs are also current and potential drug targets; compounds inhibiting CYP are antifungal and anti-protozoan agents, and potentially similar compounds may be useful against some bacterial diseases such as tuberculosis. Of note is the diversity of CYP requirements within an organism, ranging from Escherichia coli that has no CYPs as in many bacteria, to Mycobacterium smegmatis that has 40 representing 1% of coding genes. The basidiomycete fungus Phanerochaete chrysosporium surprised all when it was found to contain a hundred or more CYPs. The functional genomic investigation of these orphan CYPs is a major challenge for the future.

Microbial transformations of steroids--XII. Progesterone hydroxylation profiles are modulated by post-translational modification of an electron transfer protein in Streptomyces roseochromogenes

When Streptomyces roseochromogenes strain 10984 was incubated with exogenous progesterone for 25 h the major monohydroxylated metabolite, 16alpha-hydroxyprogesterone was produced in 3.6 fold excess to the minor metabolite 2beta,16alpha-dihydroxyprogesterone. In a reconstituted system containing highly purified progesterone 16alpha-hydroxylase cytochrome P-450, and electron transfer proteins ferredoxin-like redoxin (roseoredoxin) and redoxin reductase (roseoredoxin reductase), both metabolites were produced but in a 10:1 ratio. When S. roseochromogenes was pre-incubated for 8 h with 0.32 mM progesterone and the purified components of the hydroxylase system incubated as before, the ratio of 16alpha-hydroxyprogesterone to 2beta,16alpha-dihydroxyprogesterone produced decreased to 2.8:1, virtually identical to the ratio in whole cell transformations. Reconstitution assays containing all combinations of hydroxylase proteins purified from progesterone pre-incubated and control cells showed that the roseoredoxin was solely responsible for the observed changes in in vitro metabolite ratios. The fact that the lower 16alpha-hydroxyprogesterone to 2beta,16alpha-dihydroxyprogesterone ratio was also obtained when S. roseochromogenes was exposed to 0.335 mM cycloheximide for 8 h prior to the progesterone pre-incubation, pointed to post-translation modification of the roseoredoxin. Separation of two isoforms of roseoredoxin by isoelectric focusing supported this proposition.

Substrate binding to 15beta-hydroxylase (CYP106A2) probed by FT infrared spectroscopic studies of the iron ligand CO stretch vibration

CYP106A2 has been expressed in E. coli with a high yield of up to 130 mg per litre of culture, purified to electrophoretic homogenity and found to be active in 15beta-hydroxylation of deoxycorticosterone using the adrenal redox proteins adrenodoxin and adrenodoxin reductase. Inspite of catalytic activity no substrate binding was detectable by UV-Vis spectroscopy. In contrast, an effect of substrate binding has been detected using the CO stretch mode infrared spectrum indicating that deoxycorticosterone binds in the heme pocket near the iron ligand.

Microbial transformations of steroids-XI. Progesterone transformation by Streptomyces roseochromogenes-purification and characterisation of the 16alpha-hydroxylase system

Streptomyces roseochromogenes, NCIB 10984, contains a cytochrome P450 which, in conjunction with two indigenous electron transfer proteins, roseoredoxin and roseoredoxin reductase, hydroxylates exogenous progesterone firstly to 16alpha-hydroxyprogesterone and thereafter in a second phase bioconversion to 2beta,16alpha-dihydroxyprogesterone. The progesterone 16alpha-hydroxylase P450 and the two electron transfer proteins have been purified to homogeneity. A reconstituted incubation containing these three purified proteins and NADH, the natural electron donor, produced identical hydroxy-progesterone metabolites as in intact cells. Peroxy and hydroperoxy compounds act in a shortened form of the cycle known as the 'peroxide shunt' by replacing the natural pathway requirement for the electron donor NADH, the electron transfer proteins and molecular O2, the terminal electron acceptor. In an NaIO4 supported incubation, the initial rate of progesterone hydroxylation was marginally higher (1.62 mmol progesterone/mmol P-450/h) than in the reconstituted natural incubation (1.18 mmol progesterone/mmol P-450/h) but the product yield was significantly lower, 0.45 mol hydroxyprogesterone produced/mol P-450 compared to 6.0 mol hydroxyprogesterone produced/mol P-450. These yield data show that in the reconstituted natural pathway, progesterone 16alpha-hydroxylase P450 supports multiple rounds of hydroxylation in contrast to a likely single oxygenation by a minority of P450s in the peroxide shunt pathway.

cDNA sequence and deduced amino acid sequence of a fungal stress protein induced in Rhizopus nigricans by steroids

cDNA clone was isolated from lambdagt11 library prepared from Rhizopus nigricans after growing the fungus in the presence of progesterone. Northern blot analysis of total RNA showed that expression of corresponding mRNA was up-regulated in R. nigricans after treatment with different steroids and after exposure of the fungus to heat shock or osmotic stress. Sequence analysis revealed an open reading frame for a 364-amino-acid polypeptide. The predicted amino acid sequence exhibited significant similarity to several sugar epimerases in two domains common to these enzymes. Our results suggest that the analyzed cDNA is coding for a fungal stress inducible protein belonging to sugar epimerases.

Purification and characterization of NADPH-cytochrome P450 reductase from filamentous fungus Rhizopus nigricans

We report here the isolation and partial characterization of a flavoprotein, NADPH-cytochrome P450 (cytochrome c) reductase. The enzyme is a part of steroid 11 alpha-hydroxylating system and is associated with the microsomal fraction of the fungus Rhizopus nigricans. Fungal reductase was solubilized from microsomal membranes with Triton X-100 and purified to apparent homogeneity by affinity and high-performance ion-exchange chromatography. A 350-fold purification of the enzyme with specific activity of 37 mumol cytochrome c reduced/min/mg protein was achieved. A single protein band was obtained on SDS-PAGE analysis with an apparent molecular weight of 79 kDa. Purified reductase contained approximately equimolar quantities of flavin adenine dinucleotide and flavin mononucleotide per mole of the enzyme. Upon induction of the steroid hydroxylating system with progesterone the activity of microsomal NADPH-cytochrome c (P450) reductase increased 10-fold. This is in good correlation with the increase in content of fungal cytochrome P450. Purified fungal flavoprotein was active in a reconstituted system with cytochrome P450 C21 from adrenal gland but could not replace adrenodoxin reductase in the mitochondrial steroid 11 beta-hydroxylating system. We were able to confirm the role of the enzyme by reconstituting steroid 11 alpha-hydroxylating activity from the separated components NADPH-cytochrome P450 reductase and cytochrome P450, partly purified from fungal microsomes.

The inducible and cytochrome P450-containing dehydroepiandrosterone 7alpha-hydroxylating enzyme system of Fusarium moniliforme

7Alpha-hydroxylation of DHEA by Fusarium moniliforme was investigated with regard to inducibility and characterization of the responsible enzyme system. Using GC/MS, the 7-hydroxylated metabolites of DHEA produced after biotransformation by Fusarium moniliforme mycelia were identified. The strain of Fusarium moniliforme hydroxylated DHEA predominantly at the 7alpha-position, with minor hydroxylation occurring at the 7beta-position. Constitutive 7alpha-hydroxylation activity was low, but DHEA induced the enzyme complex responsible for 7alpha-hydroxylation via an increase in protein synthesis. DHEA 7alpha-hydroxylase was found to be mainly microsomal, and the best production yields of 7alpha-hydroxy-DHEA (28.5 +/- 3.51 pmol/min/mg protein) were obtained with microsomes prepared from 18-h-induced mycelia. Kinetic parameters (KM=1.18 +/- 0.035 microM and Vmax=909 +/- 27 pmol/min/mg protein) were determined. Carbon monoxide inhibited 7alpha-hydroxylation of DHEA by microsomes of Fusarium moniliforme. Also, exposure of mycelia to DHEA increased microsomal P450 content. These results demonstrated that: (i) DHEA is 7alpha-hydroxylated by microsomes of Fusarium moniliforme; (ii) DHEA induces Fusarium moniliforme 7alpha-hydroxylase; (iii) this enzyme complex contains a cytochrome P450.

Involvement of cytochrome P-450 in the 15alpha-hydroxylation of 13-ethyl-gon-4-ene-3,17-dione by Penicillium raistrickii

The 15alpha-hydroxylation of 13-ethyl-gon-4-ene-3,17-dione (GD) with different subcellular fractions of Penicillium raistrickii i 477 was investigated. Cytochrome P-450 was shown to be involved in this reaction. The steroid transformation was inhibited by carbon monoxide, metyrapone, p-CMB, iodoacetamide, N-methylmaleimide and several metal ions. The 15alpha-hydroxylase was observed to be dependent on nicotinamide-adenine dinucleotide phosphate (NADPH) replaceable by NaIO4, and the activity was enhanced by a NADPH-regenerating system, indicating the involvement of the NADPH-cytochrome c (P-450) reductase. This was further confirmed by the inhibition of the hydroxylase activity in the presence of cytochrome c. No effect was observed in the presence of azide and antimycin A. Solubilized microsomes gave an absorption maximum at 453 nm in carbon monoxide difference spectrum, and showed a Type-I GD-binding spectrum typically for cytochrome P-450 interaction with substrate. First results about the inducibility of the enzymes involved in the 15alpha-hydroxylation of GD are shown.

Evidence for and characterization of cytochrome P-450 in Neurospora crassa

Cytochrome P-450 was detected in microsomes and presumably in cytosol of Neurospora crassa, and was found to be inducible by progesterone. In the microsomal fraction cytochrome b5 and NADPH-cytochrome c reductase activities were measurable, too. Cytochrome P-450 of Neurospora crassa is inhibited by SKF-525 A and by inhibitors of ergosterol biosynthesis. After induction of cytochrome P-450 with progesterone 11 alpha-hydroxyprogesterone as one metabolite of progesterone was detected in the culture media as well as in the mycelia. After 42 hours about 70% of progesterone were metabolized.

Microbial transformations of steroids--X. Cytochromes P-450 11 alpha-hydroxylase and C17-C20 lyase and a 1-ene dehydrogenase transform steroids in Nectria haematococca

Nectria haematococca contains four enzymes that metabolise exogenous steroids. Two of these are microsomal cytochromes P-450 which act sequentially on progesterone producing firstly, by side-chain cleavage, the C19 steroid androstenedione (C17-C20 lyase), and then, in a subsequent set of transformations, 11 alpha-hydroxylated derivatives (11 alpha-hydroxylase). Two other conversions occur after side-chain cleavage. Unsaturation, in the form of a double bond at C1-C2, is introduced into the A ring by a catalytically self-sufficient microsomal 1-ene dehydrogenase. This enzyme is specific for C19 substrates. A C17-specific oxidoreductase is also involved in the production of androstenedione and testosterone from progesterone. The lyase, 11 alpha-hydroxylase and 1-ene dehydrogenase were purified to homogeneity.

Microbial transformations of steroids--VIII. Transformation of progesterone by whole cells and microsomes of Aspergillus fumigatus

The filamentous fungus, Aspergillus fumigatus, efficiently hydroxylated exogenous progesterone producing, after 3 h of incubation, 11 alpha- and 15 beta-hydroxyprogesterone as major products, 7 beta-hydroxyprogesterone as a minor product and trace amounts of 7 beta, 15 beta- and 11 alpha, 15 beta-dihydroxyprogesterone. After 72 h the dihydroxyprogesterones were the sole metabolites in the culture medium. Microsomes, prepared by Ca2+ precipitation, catalysed only monohydroxylation of progesterone at the same sites as whole cells. Hydroxylation was dependent on NADPH (but not NADH) which was replaceable by NaIO4. Hydroxylation was inhibited by carbon monoxide and by the azole fungicide, ketoconazole. Microsomes gave a dithionite-reduced, carbon monoxide difference absorbance spectrum with a peak at 448 nm and a Type-I progesterone-binding spectrum typical of cytochrome P450 interaction with substrate. Ketoconazole inhibition studies suggest the presence of two non-inducible cytochrome P450 progesterone hydroxylases, one possessing 7 beta site-selectivity, the other 11 alpha/15 beta site-selectivity.

Purification and properties of cytochrome P-450 (P-450lun) catalyzing steroid 11 beta-hydroxylation in Curvularia lunata

Addition of 11-deoxycortisol to the culture medium of Curvularia lunata induced the increase of cytochrome P-450 content and steroid 11 beta-hydroxylase activity. The enzyme in cell-free extract produces cortisol from 11-deoxycortisol in the presence of NADPH and O2. The enzyme was partially stabilized by glycerol, 11-deoxycortisol, GSH and PMSF. The hydroxylation activity was strongly inhibited by carbon monooxide and sulfhydryl reagents. Cytochrome P-450 located on the microsomal fraction was solubilized with Triton X-100 and sodium cholate and purified to apparent homogeneity by column chromatography. The purified cytochrome P-450 (P-450lun) has a molecular mass of 60 kDa and exhibits the absorption maximum at 392 nm in the spectrum of oxidized form in the presence of 11-deoxycortisol. The reduced CO difference spectrum has a maximal peak at 448 nm. 11 beta-Hydroxylation of 11-deoxycortisol was reconstituted by cytochrome P-450lun, C. lunata NADPH-cytochrome P-450 reductase and DLPC in the presence of NADPH and O2 with a turnover number of 207 nmol/min per nmol of cytochrome P-450. The reductase and DLPC could be partially replaced with the enzyme purified from yeast or pig testis microsome and lipids purified from C. lunata, respectively. P-450lun catalyzes bifunctionally 11 beta- and 14 alpha-hydroxylations of 11-deoxycortisol. Deoxycorticosterone, progesterone, androstenedione and testosterone are hydroxylated in the similar manner.

Studies on the 14 alpha-hydroxylation of progesterone in Mucor piriformis

Cell-free extracts with high 14 alpha-hydroxylase activity were prepared from induced vegetative cell cultures of Mucor piriformis by grinding in potassium phosphate buffer (0.05 M, pH 8.0) containing glucose (0.25 M), KCl (1 mM), glutathione (1.0 mM) and glycerol (10%). Although the ideal pH for preparing the cell-free extract from vegetative cells was 8.0, the pH optimum of the hydroxylase was found to be 7.6. Microsomes (2.0 mg) prepared from the crude cell-free extract hydroxylated progesterone to 14 alpha-hydroxyprogesterone in approximately 60% yields in 30 min in the presence of NADPH and O2. Microsomes prepared from the uninduced cells did not contain any 14 alpha-hydroxylase activity. The hydroxylase activity was inhibited to a significant extent by CO and p-chloromercuribenzoate whereas moderate inhibition was noticed in the presence of SKF-525A, metyrapone and N-methylmaleimide indicating the possible involvement of the cytochrome P-450 system in the reaction. The membrane bound hydroxylase was solubilized using Triton X-100 and the solubilized fraction contained nearly 35% of the original hydroxylase activity.

Identification of progesterone binding sites in the plasma membrane of the filamentous fungus Cochliobolus lunatus

Plasma membrane associated binding sites for progesterone have been identified in the filamentous fungus Cochliobolus lunatus (C. lunatus). The Kd for progesterone determined by Scatchard analysis was 13.9 +/- 5.7 nM and the Bmax was 250-360 fmol/mg protein. A broad ligand specificity of these binding sites is suggested by the observation that all tested steroids, regardless of their capability to act as inducers of the 11 beta-steroid hydroxylase, competed at 250-fold excess with [3H]progesterone binding. A biological role of these plasma membrane associated steroid binding sites is nevertheless suggested since in protoplasts which were devoid of them, 11 beta-steroid hydroxylase could not be induced. Progesterone binding sites were present in the plasma membrane as well as in the cytosol and were detected in this fraction, in contrast to the plasma membrane fraction, only under special experimental conditions in respect to redox state. Kd and Bmax of cytosol binding sites were of the same order of magnitude compared to the plasma membrane progesterone binding sites. Ethisterone and 4-cholesten-3-one which cannot induce 11 beta-hydroxylase competed efficiently for plasma membrane binding sites; ethisterone, however also competed for cytosol binding sites and acted, in contrast with 4-cholesten-3-one, as antagonist in the induction of 11 beta-steroid hydroxylase in C. lunatus. On the basis of presented evidence we concluded that C. lunatus contains binding sites for steroids in the plasma membrane and in the cytosol and that both types of binding site are involved in the process of induction of enzymes which transform steroids in this fungus.

Steroid 11ß-hydroxylation by a fungal microsomal cytochrome P450

The steroid 11ß-hydroxylase activity of the fungus Cochliobolus lunatus was increased about 100-fold by cultivation of mycelia for 4-5 h with 20-hydroxymethyl-1,4-pregnadien-3-one. Cell-free extracts revealed a maximum activity of 45 nmol 11ß-hydroxyprogesterone/h·mg protein in the 100,000 g pellet fraction. The 11ß-hydroxylation was dependent on NADPH. The formation of 11ß-hydroxyprogesterone correlated linearly with the cytochrome P450 concentration. The fungal 11ß-hydroxylase transformed both 21-methyl and 21-hydroxymethyl steroids. The enzyme showed a broader substrate specificity and lower regioselectivity as compared with the adrenal cytochrome P45011ß system. The fungal cytochrome P450 was partially purified to a specific content of 700 pmol P450/mg protein. Western blots showed that polyclonal antibodies against cytochrome P45011α from Rhizopus nigricans cross-react with a 60 kD protein of partially purified fractions. The NADPH-cytochrome c reductase was enriched up to a specific activity of 20 U/mg protein. Polyclonal antibodies against NADPH-cytochrome P450 reductases from Candida maltosa and rat liver cross-reacted with the fungal reductase. It is concluded that the 11ß-hydroxylase of Cochliobolus lunatus represents a microsomal two-component monooxygenase system which is composed of a cytochrome P450 (M(r) 60 kD) and a NADPH-cytochrome P450 reductase (M(r) 79 kD).

Bioconversion of steroids by Cochliobolus lunatus--II. 11 beta-hydroxylation of 17 alpha, 21-dihydroxypregna-1,4-diene-3,20-dione 17-acetate in dependence of the inducer structure

The 11 beta-hydroxylase of the filamentous fungus Cochliobolus lunatus m 118 was induced with the substrate 17 alpha, 21-dihydroxypregna-1,4-diene-3,20-dione 17-acetate (11 beta-deoxyprednisolone 17-acetate) itself, substrate analogues, different pregnane compounds, sterols, intermediates of microbial sterol side-chain degradation or bile acids, together with 24 different steroids in a standardized test system. The resulting 11 beta-hydroxylation rate, leading to prednisolone 17-acetate and prednisolone, respectively, was determined and compared with the hydroxylation rate of non-induced cultures. The transformation yield strongly depended on the inducer structure. The microbial sterol side-chain degradation intermediates (20S)-20-hydroxymethylpregn-4-en-3-one and the corresponding pregna-1,4-diene compound caused the highest induction effects (induction factors 5.1 and 4.9, respectively). The metabolism of (20S)-20-hydroxymethylpregna-1,4-dien-3-one during the cultivation was elucidated. The induction effect decreased with the rising oxidation of the inducer. The significant increase of the 11 beta-hydroxylation rate of 1-dehydro-pregnane substrates by specific induction allows alternative pathways to glucocorticoid partial syntheses.

Localization of the gene encoding steroid hydroxylase cytochrome P-450 from Rhizopus nigricans inside a HindIII fragment of genomic DNA

The gene encoding steroid inducible cytochrome P450 of Rhizopus nigricans ATCC 6227b has been found inside a HindIII fragment of the genomic DNA by hybridization with a partial length cDNA probe. The latter was isolated by immunoscreening a cDNA library prepared in the lambda gt11 expression system and identified on the basis of inducibility and sequence analysis. The nucleotide sequence of the cDNA probe revealed a coding sequence for the heme binding segment characteristic of the P450 gene family.

Microbial transformation of steroids--VII. Hydroxylation of progesterone by extracts of Phycomyces blakesleeanus

Post mitochondrial supernatants (S-12 extracts) were prepared from Phycomyces blakesleeanus by grinding washed and frozen mycelial cakes in fine sand and extracting the paste produced with buffer containing Tris-HCl pH 7.8 (0.1 M), EDTA (0.01 M), dithiothreitol (5 mM) and glycerol (10% v/v). The S-12 extracts, obtained in this way, reproducibly hydroxylated progesterone, producing 7 alpha- and 15 beta-hydroxyprogesterone the major products of whole-cell transformation. Cell-free progesterone hydroxylation was found to be approximately linearly dependent on extract concentration, to require reduced NADP (partly replaceable by NADH), and to be dependent on progesterone (apparent Km calculated to be 4 mM). K+ and Mg2+ were found not to be required. Maximum progesterone hydroxylation occurred after 2 h at pH 7.8 and at 24 degrees C. Using optimum conditions S-12 extracts were capable of hydroxylating between 5 and 15% of added progesterone (0.2 mM). Hydroxylation was found to be partially inhibited by carbon monoxide (ca 40%) and almost completely inhibited by azoles, ketoconazole and diconazole. The NADPH and molecular oxygen requirements were replaceable by NaIO4. These findings strongly suggest that hydroxylation was being catalyzed by cytochrome P-450. This was confirmed by preparing progesterone-hydroxylating microsomes and Triton N-101-solubilized microsome extracts, and by obtaining a dithionite-reduced carbon monoxide-difference absorption spectrum peak at 455 nm in the solubilized microsome extracts.

Factors affecting the induction of 11 alpha-hydroxylase of progesterone in the filamentous fungus Rhizopus nigricans

The 11 alpha-hydroxylase of progesterone was induced in the filamentous fungus Rhizopus nigricans ATCC 6227b with different steroids as inducers and the induction process was optimized in regard to the age of the mycelium, to the concentration of the inducer and to the time of induction. Deoxycorticosterone and testosterone, steroids with higher polarity of the side-chain than progesterone, although poorer substrates for in vivo hydroxylation than progesterone, induced more enzyme compared to progesterone. Other alterations in the steroidal ring system examined diminished the induction capability of the inducing steroid to different extent. The highest 11 alpha-hydroxylating activity, if expressed on the basis of mycelial wet weight, was achieved with 18 h old mycelium which was induced for 2 h with 0.30 mM deoxycorticosterone.

Microbial transformation of steroids--II. Transformations of progesterone, testosterone and androstenedione by Phycomyces blakesleeanus

Phycomyces blakesleeanus transformed progesterone, testosterone and androstenedione into mixtures of products. Five monohydroxylated metabolites were obtained in reasonable yields from the progesterone transformation. Only 7 alpha- and 15 beta-hydroxyprogesterone have been reported previously from this organism. We find that it gives these two metabolites and also 6 beta-, 14 alpha- and 15 alpha-hydroxyprogesterone as major products. Five compounds were also purified from testosterone transformation mixtures. Two of these were monohydroxylated, two were ring A dehydrogenation products, and two were oxidised at C-17. The products were identified as 6 beta-hydroxytestosterone, 7 alpha-hydroxytestosterone, androsta-1,4-diene-3,17-dione (1-dehydroandrostenedione), 17 beta-hydroxyandrosta-1,4-diene-3-one (1-dehydrotestosterone) and androstenedione. All five metabolites were produced in reasonable yields, although hydroxylation was the minor transformation in this case. Only two significant products were formed from androstenedione. Both were reduced at C-17; one was also monohydroxylated. They were testosterone and 14 alpha-hydroxytestosterone. The testosterone and androstenedione transformation products have not been reported previously for this organism. We also report for the first time the preparation of P. blakesleeanus cell-free extracts which transformed progesterone reasonably efficiently and faithfully in vitro, although the proportions of each product varied from one extract to another.

Microbial transformations of steroids--I. Rare transformations of progesterone by Apiocrea chrysosperma

When Apiocrea chrysosperma is incubated with progesterone for 7 days in a peptone, yeast-extract medium, eight major metabolites are produced. Each compound has been purified and its structure determined by high-field 1D and 2D 1H nuclear magnetic resonance (NMR) spectroscopy. A clear synthetic pattern is recognisable. The products have been formed by multiple transformation reactions, usually double hydroxylations. Seven compounds are tertiary alcohols in which the hydroxyl group is located on the underside of the progesterone skeleton at either the axial 9 alpha- or the axial 14 alpha-site. One compound has hydroxyl groups at both these sites. Five metabolites are also secondary progesterone alcohols, the hydroxyl groups being at the 6 beta-, 15 alpha- or 15 beta-sites. Two compounds are monohydroxy metabolites; one is dehydrogenated in ring B and the other has lost the pregnane side-chain. The structures of the eight metabolites are 6 beta, 9 alpha-dihydroxyprogesterone; 6 beta, 14 alpha-dihydroxyprogesterone; 9 alpha, 14 alpha-dihydroxyprogesterone; 9 alpha, 15 beta-dihydroxyprogesterone, 14 alpha, 15 alpha-dihydroxyprogesterone; 14 alpha, 15 beta-dihydroxyprogesterone; 14 alpha-hydroxypregna-4,6-diene-3,20-dione and 15 alpha-hydroxyandrostene-3,17-dione. All compounds, except the last one, are biologically rare because they are not products of mammalian progesterone or androstenedione metabolism. They would be difficult to synthesise chemically. We believe that the compounds, 9 alpha, 15 beta-dihydroxyprogesterone; 14 alpha, 15 alpha-dihydroxyprogesterone and 14 alpha-hydroxypregn-4,6-diene-3,20-dione, have not been reported previously as microbial transformation products of progesterone.

Biotransformations of steroids

Different types of microbiological transformation of steroids are reviewed, with special attention given to bioconversions applied in the manufacturing of steroid hormones, i.e., 11 alpha- 11 beta-, 16 alpha-, 17 alpha-hydroxylations and 1-dehydrogenation. Availability and utilization of raw materials for industrial production of steroids of the estrane, androstane, and pregnane series are discussed. Among the current trends in steroid research of a practical nature, immobilization of enzymes and living cells and the spore process are emphasized as alternative techniques of steroid transformation of possible future importance. Efforts to recognize, in cell-free preparations, the components of steroid-transforming enzyme systems as well as the cellular mechanisms of control of their biosynthesis and activity are described in order to illustrate the main subjects of current basic investigation in steroid bioconversion.

Characterization of progesterone 11 alpha-hydroxylase of Aspergillus ochraceus TS: a cytochrome P-450 linked monooxygenase

The monooxygenase of Aspergillus ochraceus TS capable of 11 alpha-hydroxylation of progesterone has been resolved into three components and characterized as (i) cytochrome P450, (ii) NADPH-cytochrome P450-reductase and (iii) phosphatidyl choline. The 11 alpha-hydroxylase was observed to be NADPH dependent, and hydroxylation was enhanced by a NADPH regenerating system. This fungal monooxygenase has many features in common with that of mammalian liver microsomes. The role of mammalian cytochrome P450 inducers were tested for induction of 11 alpha-hydroxylase in Aspergillus ochraceus TS. The reductase has been partially purified.

Hydroxylation of steroids with 11 alpha-hydroxylase of Rhizopus nigricans

Three groups of 3-keto-4-ene steroids with different side chains were used as substrates for the induced 11 alpha-hydroxylase of Rhizopus nigricans. The highest total bioconversion as well as the highest yield of 11 alpha-hydroxylated product is found using progesterone as substrate. By changing the polarity of the side chain, much higher yields of 6 beta- and 7 beta-hydroxylated products relative to 11 alpha-hydroxylated product are obtained. Our results thus provide evidence for the importance of the side chain in steroid-enzyme interactions.

Resolution and reconstitution of cytochrome P-450 containing steroid hydroxylation system of Rhizopus nigricans

11 alpha-hydroxylation of progesterone in the eucaryotic filamentous fungus Rhizopus nigricans is catalyzed by a monooxygenase. Three components of this multienzyme system, cytochrome P-450, rhizoporedoxin and a FAD containing rhizoporedoxin reductase have been separated from the postmitochondrial fraction on DEAE cellulose. Using NADPH as electron donor we showed that the presence of all three components was necessary for the reconstitution of the active electron transport chain.

Resolution and reconstitution of the NADPH-cytochrome c (P-450) reductase induced by progesterone in Rhizopus nigricans

The NADPH-cytochrome c (P-450) reductase induced in the filamentous fungus Rhizopus nigricans as a component of 11 alpha-hydroxylase of progesterone was resolved by DEAE-cellulose chromatography into two components. One of the components is an iron-sulfur protein (rhizoporedoxin), whereas the other component is a protein with reductase activity dependent on NADPH (rhizoporedoxin reductase). As shown in the reconstitution assay, the NADPH-cytochrome c (P-450) reductase activity was restored upon combination of these two proteins.

Optimum conditions for ursodeoxycholic acid production from lithocholic acid by Fusarium equiseti M41

Ursodeoxycholic acid dissolves cholesterol gallstones in humans. In the present study optimum conditions for ursodeoxycholic acid production by Fusarium equiseti M41 were studied. Resting mycelia of F. equiseti M41 showed maximum conversion at 28 degrees C, pH 8.0, and dissolved oxygen tension of higher than 60% saturation. Monovalent cations, such as Na+, K+, and Rb+, stimulated the conversion rate more than twofold. In the presence of 0.5 M KCl, the initial uptake rate and equilibrium concentration of lithocholic acid (substrate) were enhanced by 5.7- and 1.7-fold, respectively. We confirmed that enzyme activity catalyzing 7 beta-hydroxylation of lithocholic acid was induced by substrate lithocholic acid. The activity in the mycelium was controlled by dissolved oxygen tension during cultivation: with a dissolved oxygen tension of 15% and over, the activity peak appeared at 25 h of cultivation, whereas the peak was delayed to 34 and 50 h with 5 and 0% dissolved oxygen tension, respectively. After reaching the maximum, the 7 beta-hydroxylation activity in the mycelium declined rapidly at pH 7.0, but the decline was retarded by increasing the pH to 8.0. Several combinations of operations, such as pH shift (from pH 7 to 8), addition of 0.5 M KCl, and dissolved oxygen control, were applied to the production of ursodeoxycholic acid in a jar fermentor, and a much larger amount of ursodeoxycholic acid (1.2 g/liter) was produced within 96 h of cultivation.