James A. Wright scite author profile

Mechanistic aspects of the biosynthesis of oestrogen have been studied with a microsomal preparation from full-term human placenta. The overall transformation, termed the aromatization process, involves three steps using O2 and NADPH, in which the C-19 methyl group of an androgen is oxidised to formic acid with concomitant production of the aromatic ring of oestrogen: [Formula: see text] To study the mechanism of this process in terms of the involvement of the oxygen atoms, a number of labelled precursors were synthesized. Notable amongst these were 19-hydroxy-4-androstene-3,17-dione (II) and 19-oxo-4-androstene-3,17-dione (IV) in which the C-19 was labelled with2H in addition to18O. In order to follow the fate of the labelled atoms at C-19 of (II) and (IV) during the aromatization, the formic acid released from C-19 was benzylated and analysed by mass spectrometry. Experimental procedures were devised to minimize the exchange of oxygen atoms in substrates and product with oxygens of the medium. In the conversion of the 19-[18O] compounds of types (II) and (IV) into 3-hydroxy-1,3,5-(10)-oestratriene-17-one (V, oestrone), it was found that the formic acid from C-19 retained the original substrate oxygen. When the equivalent16O substrates were aromatized under18O2, the formic acid from both substrates contained one atom of18O. It is argued that in the conversion of the 19-hydroxy compound (II) into the 19-oxo compound (IV), the C-19 oxygen of the former remains intact and that one atom of oxygen from O2 is incorporated into formic acid during the conversion of the 19-oxo compound (IV) into oestrogen. This conclusion was further substantiated by demonstrating that in the aromatization of 4-androstene-3,17-dione (I), both the oxygen atoms in the formic acid originated from molecular oxygen. 10β-Hydroxy-4-oestrene-3,17-dione formate, a possible intermediate in the aromatization, was synthesized and shown not to be converted into oestrogen. In the light of the cumulative evidence available to date, stereochemical aspects of the conversion of the 19-hydroxy compound (II) into the 19-oxo compound (IV), and mechanistic features of the C-10–C-19 bond cleavage step during the conversion of the 19-oxo compound (IV) into oestrogen are discussed.

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Modulation of the activity of human 17 α-hydroxylase-17,20-lyase (CYP17) by cytochrome b5: endocrinological and mechanistic implications

Lee-Robichaud

1995

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Using NADPH-cytochrome P-450 reductase as electron donor the homogeneous pig 17 alpha-hydroxylase-17,20-lyase (CYP17) was shown to catalyse the conversion of delta 5, as well as delta 4, steroids (pregnenolone and progesterone respectively) predominantly into the corresponding 17 alpha-hydroxylated products. The latter were then cleaved by the lyase (desmolase) activity of the enzyme into androgens. Cytochrome b5 stimulated both these activities, but its most noticeable effect was on the formation of delta 16-steroids, which compulsorily required the presence of cytochrome b5. These results on the pig enzyme confirm the original findings [Nakajin, Takahashi, Shinoda and Hall (1985) Biochem. Biophys. Res. Commun. 132, 708-713]. The human CYP17 expressed in Escherichia coli [Imai, Globerman, Gertner, Kagawa and Waterman (1993) J. Biol. Chem. 268, 19681-19689] was also purified to homogeneity and was found to catalyse the hydroxylation of pregnenolone and progesterone without requiring cytochrome b5. Like the pig CYP17, the human CYP17 also catalysed the cytochrome b5-dependent direct cleavage of pregnenolone into the delta 5,16-steroid, but unlike it the human enzyme did not cleave progesterone at all. 17 alpha-Hydroxypregnenolone was, however, cleaved into the corresponding androgen but only in the presence of cytochrome b5. 17 alpha-Hydroxyprogesterone was a poor substrate for the human CYP17; although it was converted into androstenedione in the presence of cytochrome b5 its K(m) was 5 times higher and Vmax. 2.6 times lower than those for the hydroxylation of progesterone. The endocrinological and mechanistic implications of these results are discussed.

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Urban groundwater quality in sub-Saharan Africa: current status and implications for water security and public health

et al. 2017

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Groundwater resources are important sources of drinking water in Africa, and they are hugely important in sustaining urban livelihoods and supporting a diverse range of commercial and agricultural activities. Groundwater has an important role in improving health in sub-Saharan Africa (SSA). An estimated 250 million people (40% of the total) live in urban centres across SSA. SSA has experienced a rapid expansion in urban populations since the 1950s, with increased population densities as well as expanding geographical coverage. Estimates suggest that the urban population in SSA will double between 2000 and 2030. The quality status of shallow urban groundwater resources is often very poor due to inadequate waste management and source protection, and poses a significant health risk to users, while deeper borehole sources often provide an important source of good quality drinking water. Given the growth in future demand from this finite resource, as well as potential changes in future climate in this region, a detailed understanding of both water quantity and quality is required to use this resource sustainably. This paper provides a comprehensive assessment of the water quality status, both microbial and chemical, of urban groundwater in SSA across a range of hydrogeological terrains and different groundwater point types. Lower storage basement terrains, which underlie a significant proportion of urban centres in SSA, are particularly vulnerable to contamination. The relationship between mean nitrate concentration and intrinsic aquifer pollution risk is assessed for urban centres across SSA. Current knowledge gaps are identified and future research needs highlighted.

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The Mechanism of the Acyl-Carbon Bond Cleavage Reaction Catalyzed by Recombinant Sterol 14α-Demethylase of Candida albicans (Other Names Are: Lanosterol 14α-Demethylase, P-45014DM, and CYP51)

Shyadehi

Lamb

Kelly

et al. 1996

Journal of Biological Chemistry

141

116

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The Candida albicans sterol 14␣-demethylase gene (P-450 14DM , CYP51) was transferred to the yeast plasmid YEp51 placing it under the control of the GAL10 promoter. The resulting construct (YEp51:CYP51) when transformed into the yeast strain GRF18 gave a clone producing 1.5 mol of P-450/liter of culture, the microsomal fraction of which contained up to 2. O 2 and the released formic acid analyzed by mass spectrometry. The results showed that in the acyl-carbon bond cleavage step (i.e. the deformylation process) the original carbonyl oxygen at C-32 of the precursor is retained in formic acid and the second oxygen of formate is derived from molecular oxygen; precisely the same scenario that has previously been observed for the acyl-carbon cleavage steps catalyzed by aromatase (P-450 arom ) and 17␣-hydroxylase-17,20-lyase (P-450 17␣ ,CYP17). In the light of these results the mechanism of the acyl-carbon bond cleavage step catalyzed by the 14␣-demethylase is considered.

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Mechanism of the Acyl-Carbon Cleavage and Related Reactions Catalyzed by Multifunctional P-450s: Studies on Cytochrome P-45017.alpha.

Akhtar¹,

Corina²,

Miller³

et al. 1994

Biochemistry

119

105

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It is now well-known that conventional cytochrome P-450s catalyze hydroxylation reactions using an iron mono-oxygen species, the structure of which, as inferred from chemical model studies, may be drrepresented by the following canonical forms: FeV==O<-->(.+)FeIV==O<-->FeIV--O(.). Certain multifunctional P-450s, notably those involved in steroid biosynthesis, catalyze, in addition to hydroxylation reactions, an acyl-carbon cleavage process in which the participation of an iron peroxide intermediate, FeIII--OOH, has been suggested. However the possibility still exists that the C--C bond cleavage may also occur using the FeV==O species. We have scrutinized the chemical consequences of involving either an FeV==O or an FeIII--OOH species for five different C--C bond cleavage reactions. With respect to the status as well as the origin of hydrogen and oxygen atoms, in four of the examples the mechanism involving the FeV==O species makes the same prediction as that using the iron peroxide intermediate, that is, the incorporation of an atom of oxygen from O2 into acyl part of the cleaved fragment. The fifth example, however, involving the formation, with pig testes microsomes, of 17 alpha-hydroxyandrogen (androst-5-ene-3 beta,17 alpha-diol) from pregnenolone, presents an interesting contrast--in this case different outcomes are predicted by the two mechanisms. These possibilities have been experimentally evaluated using substrates stereo- and regiospecifically labeled with heavy isotopes and incubated with pig testes microsomes under either 16O2 or 18O2.(ABSTRACT TRUNCATED AT 250 WORDS)

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James A. Wright

Mechanistic studies on C-19 demethylation in oestrogen biosynthesis

Modulation of the activity of human 17 α-hydroxylase-17,20-lyase (CYP17) by cytochrome b5: endocrinological and mechanistic implications

Urban groundwater quality in sub-Saharan Africa: current status and implications for water security and public health

The Mechanism of the Acyl-Carbon Bond Cleavage Reaction Catalyzed by Recombinant Sterol 14α-Demethylase of Candida albicans (Other Names Are: Lanosterol 14α-Demethylase, P-45014DM, and CYP51)

Mechanism of the Acyl-Carbon Cleavage and Related Reactions Catalyzed by Multifunctional P-450s: Studies on Cytochrome P-45017.alpha.

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