Other conceivable renditions of some of the oxidative processes used in the biosynthesis of steroid hormones.

The generally accepted version (GAV) of the chemical processes by which the steroid hormones are biosynthesized cannot be considered to be an inerrant description of in vivo processes. Customarily this version is derived by piecing together the results obtained from several independent artificial in vitro incubation experiments. Extrapolation of such results from in vitro to in vivo requires untested assumptions which introduce varying degrees of uncertainty. In vitro incubation experiments reveal only what is possible; not what actually prevails in situ. Presented here are hypothetical alternative renditions of some of the oxidative processes involved in steroidogenesis. These versions suggest that some cytochrome P-450's catalyze the introduction of both oxygen atoms of dioxygen into an appropriate sterol precursor. The products are conceived as oxygen free radicals (peroxy or 1,2-cyclic peroxy) which serve as the "reactive intermediates" (the precursors) for the hormones. The true intermediates are not stable, isolable, hydroxylated compounds as they are customarily portrayed in the GAV. Central to these new renditions is the hypothesis that the appropriate P-450 introduces dioxygen into the precursor yielding either: A, a 20 peroxy sterol species or B, a species oxygenated at both C-17 and C-20 or C, a species oxygenated at both C-20 and C-21. In this hypothesis, A would serve as the precursor for progesterone, B, for the C19-androgens and C18-estrogens and C, for the mineralocorticoids (corticosterone and aldosterone) and the glucocorticoid (cortisol). How this version of steroidogenesis can be used to understand the etiologies of various genetically derived enzyme deficiency diseases of the adrenal and ovaries will be discussed. If as proposed here, the various polyfunctional cytochromes (P-450(scc), P-450(c17,) P-45011B1 (P-450(cortisol)), P-45011B2 (P-450(aldo)), etc.) catalyze conversions that are different from simple hydroxylations, the labels usually given these deficiency diseases may not be appropriate. More importantly, these new conceptions may clarify the etiology of some of the characteristic symptoms of these diseases that are not now adequately explained by the GAV.

New assumptions about oxidative processes involved in steroid hormone biosynthesis: is the role of cytochrome P-450-activated dioxygen limited to hydroxylation reactions or are dioxygen insertion reactions also possible?

The traditional conception of the chemical pathways leading to the formation of the steroid hormones is derived by piecing together the results of several independent in vitro incubation experiments. The results of these experiments have led to the assumption that some relevant cytochrome P-450's (P-450scc, P-450arom, P-450aldo, etc.) are "polyfunctional" and catalyze several successive hydroxylation reactions, which lead to the formation of the hormonal products. This essay offers an alternative view. It advances the suggestion that the oxygenated intermediates in the relevant biosynthetic conversions are reactive species that are formed by addition of both atoms of dioxygen onto two neighboring carbon atoms of steroidal precursors. Space-filled Stuart molecular models, generated by a computer program, suggest that the oxidized intermediates resemble hydroperoxides or cyclic peroxides (1,2-dioxanes). For the aromatization process required for estrogen biosynthesis, the atoms of dioxygen are bonded to C-2 and C-19 of the C19-precursor. For aldosterone formation, dioxygen is bonded to C-11 and C-18 of an appropriate precursor. Moreover, the results obtained from a computer program that provides information about "molecular mechanics" (bond angles and bond distances as well as total potential energies for each conformation of a molecule) suggest that consideration be given to the possibility that cortisol also can be biosynthesized by P-450-activated dioxygen addition to C-11 and C-17 of an appropriate precursor. Neither the traditional view of steroidogenic pathways nor the suggestions advanced here have been established by compelling experimental findings. Both hypotheses are saddled with untested assumptions, which are necessary because the dynamic processes can only be discerned by indirect means. The origins of some naturally occurring steroids hydroxylated at C-17, C-18 and C-19 are examined in the light of the suggestions made in this essay.

The detection and quantitation of free desmosine and isodesmosine in human urine and their peptide-bound forms in sputum.

Desmosine (D) and isodesmosine (I), the intramolecular crosslinking amino acids that occur in chains of elastin, have now been found in free form in human urine. Until now, these amino acids (M(r) = 526) were found to occur in urine only as higher molecular weight (M (r) = 1,000-1,500) peptides. Thus, the previously used analytical methods required, as the first step, acid hydrolysis of the urine at elevated temperature to liberate D and I from their peptides. The analytical method described here uses HPLC followed by electrospray ionization MS for the detection and quantitation of free D and I in unhydrolyzed urine. Identities of both D and I were established by their retention times on LC and by their mass ion at 526 atomic mass units, characteristic of each compound. The sensitivity of the method is 0.10 ng. The average values of free D and I in the urine of seven healthy subjects were 1.42 +/- 1.16 and 1.39 +/- 1.04 microg/g of creatinine, respectively. After acid hydrolysis of the urine, the amounts of D and I were 8.67 +/- 3.75 and 6.28+/-2.87 microg/g of creatinine, respectively. The method was also successfully used to measure peptide-bound D and I levels in the sputum of patients with chronic obstructive pulmonary disease.

The detection of 20S-hydroxycholesterol in extracts of rat brains and human placenta by a gas chromatograph/mass spectrometry technique.

The presence of 20(S)-hydroxycholesterol in rat brains and human placenta has been established using the gas chromatography/mass spectrometry (GC/MS) select ion monitoring (SIM) technique. Identification was ensured by three criteria: the specific retention time when the compound emerges from the gas chromatogram and the two m/z ions (201 and 461amu) which are characteristic of its mass spectrum. The possible role of 20(S)-hydroxycholesterol in steroid hormone biosynthesis and in other biological processes is discussed.