Steroid

Complex chemical diagram
Steroid ring system: The parent ABCD steroid ring system (hydrocarbon framework) is shown with IUPAC-approved ring lettering and atom numbering.[1]:1785f

A steroid is an organic compound with four rings arranged in a specific molecular configuration. Examples include the dietary lipid cholesterol, the sex hormones estradiol and testosterone[2]:10–19 and the anti-inflammatory drug dexamethasone.[3] Steroids have two principal biological functions: certain steroids (such as cholesterol) are important components of cell membranes which alter membrane fluidity, and many steroids are signaling molecules which activate steroid hormone receptors.

The steroid core structure is composed of seventeen carbon atoms, bonded in four "fused" rings: three six-member cyclohexane rings (rings A, B and C in the first illustration) and one five-member cyclopentane ring (the D ring). Steroids vary by the functional groups attached to this four-ring core and by the oxidation state of the rings. Sterols are forms of steroids with a hydroxyl group at position three and a skeleton derived from cholestane.[1]:1785f [4] They can also vary more markedly by changes to the ring structure (for example, ring scissions which produce secosteroids such as vitamin D3).

Hundreds of steroids are found in plants, animals and fungi. All steroids are manufactured in cells from the sterols lanosterol (animals and fungi) or cycloartenol (plants). Lanosterol and cycloartenol are derived from the cyclization of the triterpene squalene.[5]

Filled-in diagram of a steroid
Space-filling representation
Ball-and-stick diagram of the same steroid
Ball-and-stick representation
5α-dihydroprogesterone (5α-DHP), a steroid. The shape of the four rings of most steroids is illustrated (carbon atoms in black, oxygens in red and hydrogens in grey). The apolar "slab" of hydrocarbon in the middle (grey, black) and the polar groups at opposing ends (red) are common features of natural steroids. 5α-DHP is an endogenous steroid hormone and a biosynthetic intermediate.

Nomenclature

Chemical diagram
A gonane (steroid nucleus)

Gonane, also known as steran or cyclopentaperhydrophenanthrene, the simplest steroid and the nucleus of all steroids and sterols,[6][7] is composed of seventeen carbon atoms in carbon-carbon bonds forming four fused rings in a three-dimensional shape. The three cyclohexane rings (A, B, and C in the first illustration) form the skeleton of a perhydro derivative of phenanthrene. The D ring has a cyclopentane structure. When the two methyl groups and eight carbon side chains (at C-17, as shown for cholesterol) are present, the steroid is said to have a cholestane framework. The two common 5α and 5β stereoisomeric forms of steroids exist because of differences in the side of the largely planar ring system where the hydrogen (H) atom at carbon-5 is attached, which results in a change in steroid A-ring conformation.

Examples of steroid structures are:

In addition to the ring scissions (cleavages), expansions and contractions (cleavage and reclosing to a larger or smaller rings)—all variations in the carbon-carbon bond framework—steroids can also vary:

For instance, sterols such as cholesterol and lanosterol have an hydroxyl group attached at position C-3, while testosterone and progesterone have a carbonyl (oxo substituent) at C-3; of these, lanosterol alone has two methyl groups at C-4 and cholesterol (with a C-5 to C-6 double bond) differs from testosterone and progesterone (which have a C-4 to C-5 double bond).

Chemical diagram
Cholesterol, a prototypical animal sterol. This structural lipid and key steroid biosynthetic precursor.[1]:1785f
Chemical diagram
5α-cholestane, a common steroid core
Chemical diagram
Steroid 5α and 5β stereoisomers[1]:1786f

Species distribution and function

The following are some common categories of steroids. In eukaryotes, steroids are found in fungi, animals, and plants. Fungal steroids include the ergosterols.

Animal steroids include compounds of vertebrate and insect origin, the latter including ecdysteroids such as ecdysterone (controlling molting in some species). Vertebrate examples include the steroid hormones and cholesterol; the latter is a structural component of cell membranes which helps determine the fluidity of cell membranes and is a principal constituent of plaque (implicated in atherosclerosis). Steroid hormones include:

Plant steroids include steroidal alkaloids found in Solanaceae,[8] the phytosterols, and the brassinosteroids (which include several plant hormones). In prokaryotes, biosynthetic pathways exist for the tetracyclic steroid framework (e.g. in mycobacteria)[9] – where its origin from eukaryotes is conjectured[10] – and the more-common pentacyclic triterpinoid hopanoid framework.[11]

Types

By function

Steroids can be classified functionally. The major classes of steroid hormones, with prominent members and examples of related functions, are:

Additional classes of steroids include:

As well as the following class of secosteroids (open-ring steroids):

By structure

Intact ring system

Steroids can be classified based on their chemical composition.[12] One example of how MeSH performs this classification is available at the Wikipedia MeSH catalog. Examples of this classification include:

Chemical diagram
Cholecalciferol (vitamin D3), an example of a 9,10-secosteroid
Chemical diagram
Cyclopamine, an example of a complex C-nor-D-homosteroid
Class Example Number of carbon atoms
Cholestanes Cholesterol 27
Cholanes Cholic acid 24
Pregnanes Progesterone 21
Androstanes Testosterone 19
Estranes Estradiol 18

The gonane (steroid nucleus) is the parent 17-carbon tetracyclic hydrocarbon molecule with no alkyl sidechains.[13]

Cleaved, contracted, and expanded rings

Secosteroids (Latin seco, "to cut") are a subclass of steroidal compounds resulting, biosynthetically or conceptually, from scission (cleavage) of parent steroid rings (generally one of the four). Major secosteroid subclasses are defined by the steroid carbon atoms where this scission has taken place. For instance, the prototypical secosteroid cholecalciferol, vitamin D3 (shown), is in the 9,10-secosteroid subclass and derives from the cleavage of carbon atoms C-9 and C-10 of the steroid B-ring; 5,6-secosteroids and 13,14-steroids are similar.[14]

Norsteroids (nor-, L. norma; "normal" in chemistry, indicating carbon removal)[15] and homosteroids (homo-, Greek homos; "same", indicating carbon addition) are structural subclasses of steroids formed from biosynthetic steps. The former involves enzymic ring expansion-contraction reactions, and the latter is accomplished (biomimetically) or (more frequently) through ring closures of acyclic precursors with more (or fewer) ring atoms than the parent steroid framework.[16]

Combinations of these ring alterations are known in nature. For instance, ewes who graze on corn lily ingest cyclopamine (shown) and veratramine, two of a sub-family of steroids where the C- and D-rings are contracted and expanded respectively via a biosynthetic migration of the original C-13 atom. Ingestion of these C-nor-D-homosteroids results in birth defects in lambs: cyclopia from cyclopamine and leg deformity from veratramine.[17] A further C-nor-D-homosteroid (nakiterpiosin) is excreted by Okinawan cyanobacteriospongesTerpios hoshinota – leading to coral mortality from black coral disease.[18] Nakiterpiosin-type steroids are active against the signaling pathway involving the smoothened and hedgehog proteins, a pathway which is hyperactive in a number of cancers.

Biological significance

Steroids and their metabolites often function as signalling molecules (the most notable examples are steroid hormones), and steroids and phospholipids are components of cell membranes. Steroids such as cholesterol decrease membrane fluidity.[19] Similar to lipids, steroids are highly concentrated energy stores. However, they are not typically sources of energy; in mammals, they are normally metabolized and excreted.

Steroids play critical roles in a number of disorders, including malignancies like prostate cancer, where steroid production inside and outside the tumour promotes cancer cell aggressiveness.[20]

Biosynthesis and metabolism

Chemical-diagram flow chart
Simplification of the end of the steroid synthesis pathway, where the intermediates isopentenyl pyrophosphate (PP or IPP) and dimethylallyl pyrophosphate (DMAPP) form geranyl pyrophosphate (GPP), squalene and lanosterol (the first steroid in the pathway)

The hundreds of steroids found in animals, fungi, and plants are made from lanosterol (in animals and fungi; see examples above) or cycloartenol (in plants). Lanosterol and cycloartenol derive from cyclization of the triterpenoid squalene.[5]

Steroid biosynthesis is an anabolic pathway which produces steroids from simple precursors. A unique biosynthetic pathway is followed in animals (compared to many other organisms), making the pathway a common target for antibiotics and other anti-infection drugs. Steroid metabolism in humans is also the target of cholesterol-lowering drugs, such as statins.

In humans and other animals the biosynthesis of steroids follows the mevalonate pathway, which uses acetyl-CoA as building blocks for dimethylallyl pyrophosphate (DMAPP) and isopentenyl pyrophosphate (IPP).[21] In subsequent steps DMAPP and IPP join to form geranyl pyrophosphate (GPP), which synthesizes the steroid lanosterol. Modifications of lanosterol into other steroids are classified as steroidogenesis transformations.

Mevalonate pathway

Chemical flow chart
Mevalonate pathway

The mevalonate pathway (also called HMG-CoA reductase pathway) begins with acetyl-CoA and ends with dimethylallyl pyrophosphate (DMAPP) and isopentenyl pyrophosphate (IPP).

DMAPP and IPP donate isoprene units, which are assembled and modified to form terpenes and isoprenoids[22] (a large class of lipids, which include the carotenoids and form the largest class of plant natural products.[23] Here, the isoprene units are joined to make squalene and folded into a set of rings to make lanosterol.[24]

Lanosterol can then be converted into other steroids, such as cholesterol and ergosterol.[24][25]

Pharmacological action

Two classes of drugs target the mevalonate pathway: statins, which are used to reduce elevated cholesterol levels, and bisphosphonates, which are used to treat a number of bone-degenerative diseases.

Steroidogenesis

Chemical-diagram flow chart
Human steroidogenesis, with the major classes of steroid hormones, individual steroids and enzymatic pathways.[26] Changes in molecular structure from a precursor are highlighted in white.

Steroidogenesis is the biological process by which steroids are generated from cholesterol and changed into other steroids.[27] The pathways of steroidogenesis differ among species. The major classes of steroid hormones, as noted above (with their prominent members and functions), are the Progestogen, Corticosteroids (corticoids), Androgens, and Estrogens. Human steroidogenesis of these classes occurs in a number of locations:

Alternative pathways

In plants and bacteria, the non-mevalonate pathway uses pyruvate and glyceraldehyde 3-phosphate as substrates.[22][30]

During diseases pathways otherwise not significant in healthy humans can become utilized. For example, in one form of congenital adrenal hyperplasia an deficiency in the 21-hydroxylase enzymatic pathway leads to an excess of 17α-Hydroxyprogesterone (17-OHP) – this pathological excess of 17-OHP in turn may be converted to dihydrotestosterone (DHT, a potent androgen) through among others 17,20 Lyase (a member of the cytochrome P450 family of enzymes), 5α-Reductase and 3α-Hydroxysteroid dehydrogenase.[31]

Catabolism and excretion

Steroids are primarily oxidized by cytochrome P450 oxidase enzymes, such as CYP3A4. These reactions introduce oxygen into the steroid ring, allowing the cholesterol to be broken up by other enzymes into bile acids.[32] These acids can then be eliminated by secretion from the liver in bile.[33] The expression of the oxidase gene can be upregulated by the steroid sensor PXR when there is a high blood concentration of steroids.[34] Steroid hormones, lacking the side chain of cholesterol and bile acids, are typically hydroxylated at various ring positions or oxidized at the 17 position, conjugated with sulfate or glucuronic acid and excreted in the urine.[35]

Isolation, structure determination, and methods of analysis

Steroid isolation, depending on context, is the isolation of chemical matter required for chemical structure elucidation, derivitzation or degradation chemistry, biological testing, and other research needs (generally milligrams to grams, but often more[36] or the isolation of "analytical quantities" of the substance of interest (where the focus is on identifying and quantifying the substance (for example, in biological tissue or fluid). The amount isolated depends on the analytical method, but is generally less than one microgram.[37] The methods of isolation to achieve the two scales of product are distinct, but include extraction, precipitation, adsorption, chromatography, and crystallization. In both cases, the isolated substance is purified to chemical homogeneity; combined separation and analytical methods, such as LC-MS, are chosen to be "orthogonal"—achieving their separations based on distinct modes of interaction between substance and isolating matrix—to detect a single species in the pure sample. Structure determination refers to the methods to determine the chemical structure of an isolated pure steroid, using an evolving array of chemical and physical methods which have included NMR and small-molecule crystallography.[2]:10–19 Methods of analysis overlap both of the above areas, emphasizing analytical methods to determining if a steroid is present in a mixture and determining its quantity.[37]

Chemical synthesis

Microbial catabolism of phytosterol side chains yields C-19 steroids, C-22 steroids, and 17-ketosteroids (i.e. precursors to adrenocortical hormones and contraceptives).[38][39][40][41] The addition and modification of functional groups is key when producing the wide variety of medications available within this chemical classification. These modifications are performed using conventional organic synthesis and/or biotransformation techniques.[42][43]

Precursors

Semisynthesis

The semisynthesis of steroids often begins from precursors such as cholesterol,[41] phytosterols,[40] or sapogenins.[44] The efforts of Syntex, a company involved in the Mexican barbasco trade, used Dioscorea mexicana to produce the sapogenin diosgenin in the early days of the synthetic steroid pharmaceutical industry.[36]

Total synthesis

Some steroidal hormones are economically obtained only by total synthesis from petrochemicals (e.g. 13-alkyl steroids).[41] For example, the pharmaceutical Norgestrel begins from Methoxy-1-tetralone, a petrochemical derived from phenol.

Research awards

A number of Nobel Prizes have been awarded for steroid research, including:

See also

References

  1. 1 2 3 4 Moss GP, the Working Party of the IUPAC-IUB Joint Commission on Biochemical Nomenclature (1989). "Nomenclature of steroids, recommendations 1989" (PDF). Pure & Appl. Chem. 61 (10): 1783–1822. doi:10.1351/pac198961101783. Also available with the same authors at Carlson P, Bull JR, Engel K, Fried J, Kircher HW, Loaning KL, Moss GP, Popják G, Uskokovic MR (Dec 1989). "IUPAC-IUB Joint Commission on Biochemical Nomenclature (JCBN). The nomenclature of steroids. Recommendations 1989". European Journal of Biochemistry / FEBS. 186 (3): 429–58. PMID 2606099. doi:10.1111/j.1432-1033.1989.tb15228.x.; Also available online at "The Nomenclature of Steroids". London, GBR: Queen Mary University of London. p. 3S–1.4. Retrieved 10 May 2014.
  2. 1 2 3 Lednicer D (2011). Steroid Chemistry at a Glance. Hoboken: Wiley. ISBN 978-0-470-66084-3.
  3. Rhen T, Cidlowski JA (Oct 2005). "Antiinflammatory action of glucocorticoids--new mechanisms for old drugs" (PDF). The New England Journal of Medicine. 353 (16): 1711–23. PMID 16236742. doi:10.1056/NEJMra050541.
  4. Also available in print at Hill R, Makin H, Kirk D, Murphy G (1991). Dictionary of Steroids. London, GBR: Chapman and Hall. pp. xxx–lix. ISBN 0412270609. Retrieved 20 June 2015.
  5. 1 2 "Lanosterol biosynthesis". Recommendations on Biochemical & Organic Nomenclature, Symbols & Terminology. International Union Of Biochemistry And Molecular Biology.
  6. Victor A. Rogozkin (14 June 1991). Metabolism of Anabolic-Androgenic Steroids. CRC Press. pp. 1–. ISBN 978-0-8493-6415-0. The steroid structural base is a steran nucleus, a polycyclic C17 steran skeleton consisting of three condensed cyclohexane rings in nonlinear or phenanthrene junction (A, B, and C), and a cyclopentane ring (D).1,2
  7. Klaus Urich (16 September 1994). Comparative Animal Biochemistry. Springer Science & Business Media. pp. 624–. ISBN 978-3-540-57420-0.
  8. Wink M (Sep 2003). "Evolution of secondary metabolites from an ecological and molecular phylogenetic perspective". Phytochemistry. 64 (1): 3–19. PMID 12946402. doi:10.1016/S0031-9422(03)00300-5.
  9. Bode HB, Zeggel B, Silakowski B, Wenzel SC, Reichenbach H, Müller R (Jan 2003). "Steroid biosynthesis in prokaryotes: identification of myxobacterial steroids and cloning of the first bacterial 2,3(S)-oxidosqualene cyclase from the myxobacterium Stigmatella aurantiaca". Molecular Microbiology. 47 (2): 471–81. PMID 12519197. doi:10.1046/j.1365-2958.2003.03309.x.
  10. Desmond E, Gribaldo S (2009). "Phylogenomics of sterol synthesis: insights into the origin, evolution, and diversity of a key eukaryotic feature". Genome Biology and Evolution. 1: 364–81. PMC 2817430Freely accessible. PMID 20333205. doi:10.1093/gbe/evp036.
  11. Siedenburg G, Jendrossek D (Jun 2011). "Squalene-hopene cyclases". Applied and Environmental Microbiology. 77 (12): 3905–15. PMC 3131620Freely accessible. PMID 21531832. doi:10.1128/AEM.00300-11.
  12. Zorea, Aharon (2014). Steroids (Health and Medical Issues Today). Westport, CT: Greenwood Press. pp. 10–12. ISBN 978-1440802997.
  13. Edgren RA, Stanczyk FZ (Dec 1999). "Nomenclature of the gonane progestins". Contraception. 60 (6): 313. PMID 10715364. doi:10.1016/S0010-7824(99)00101-8.
  14. Hanson JR (Jun 2010). "Steroids: partial synthesis in medicinal chemistry". Natural Product Reports. 27 (6): 887–99. PMID 20424788. doi:10.1039/c001262a.
  15. "IUPAC Recommendations: Skeletal Modification in Revised Section F: Natural Products and Related Compounds (IUPAC Recommendations 1999)". International Union of Pure and Applied Chemistry (IUPAC). 1999.
  16. Wolfing J (2007). "Recent developments in the isolation and synthesis of D-homosteroids and related compounds". Arkivoc: 210–230.
  17. Gao G, Chen C (2012). "Nakiterpiosin". In Corey E, Li JJ. Total synthesis of natural products: at the frontiers of organic chemistry. Berlin: Springer. ISBN 978-3-642-34064-2. doi:10.1007/978-3-642-34065-9.
  18. Uemura E, Kita M, Arimoto H, Kitamura M (2009). "Recent aspects of chemical ecology: Natural toxins, coral communities, and symbiotic relationships". Pure Appl. Chem. 81 (6): 1093–1111. doi:10.1351/PAC-CON-08-08-12.
  19. Sadava D, Hillis DM, Heller HC, Berenbaum MR (2011). Life: The Science of Biology (9th ed.). San Francisco: Freeman. pp. 105–114. ISBN 1-4292-4646-4.
  20. Lubik AA, Nouri M, Truong S, Ghaffari M, Adomat HH, Corey E, Cox ME, Li N, Guns ES, Yenki P, Pham S, Buttyan R (2016). "Paracrine Sonic Hedgehog Signaling Contributes Significantly to Acquired Steroidogenesis in the Prostate Tumor Microenvironment". Int. J. Cancer. 140 (2): 358–369. PMID 27672740. doi:10.1002/ijc.30450.
  21. Grochowski LL, Xu H, White RH (May 2006). "Methanocaldococcus jannaschii uses a modified mevalonate pathway for biosynthesis of isopentenyl diphosphate". Journal of Bacteriology. 188 (9): 3192–8. PMC 1447442Freely accessible. PMID 16621811. doi:10.1128/JB.188.9.3192-3198.2006.
  22. 1 2 Kuzuyama T, Seto H (Apr 2003). "Diversity of the biosynthesis of the isoprene units". Natural Product Reports. 20 (2): 171–83. PMID 12735695. doi:10.1039/b109860h.
  23. Dubey VS, Bhalla R, Luthra R (Sep 2003). "An overview of the non-mevalonate pathway for terpenoid biosynthesis in plants" (PDF). Journal of Biosciences. 28 (5): 637–46. PMID 14517367. doi:10.1007/BF02703339.
  24. 1 2 Schroepfer GJ (1981). "Sterol biosynthesis". Annual Review of Biochemistry. 50: 585–621. PMID 7023367. doi:10.1146/annurev.bi.50.070181.003101.
  25. Lees ND, Skaggs B, Kirsch DR, Bard M (Mar 1995). "Cloning of the late genes in the ergosterol biosynthetic pathway of Saccharomyces cerevisiae--a review". Lipids. 30 (3): 221–6. PMID 7791529. doi:10.1007/BF02537824.
  26. Häggström M, Richfield D (2014). "Diagram of the pathways of human steroidogenesis". WikiJournal of Medicine. 1 (1). ISSN 2002-4436. doi:10.15347/wjm/2014.005.
  27. Hanukoglu I (Dec 1992). "Steroidogenic enzymes: structure, function, and role in regulation of steroid hormone biosynthesis". The Journal of Steroid Biochemistry and Molecular Biology. 43 (8): 779–804. PMID 22217824. doi:10.1016/0960-0760(92)90307-5.
  28. Rossier MF (Aug 2006). "T channels and steroid biosynthesis: in search of a link with mitochondria" (review; medical hypothesis). Cell Calcium. 40 (2): 155–64. PMID 16759697. doi:10.1016/j.ceca.2006.04.020. Retrieved March 20, 2017.
  29. Lubik AA, Nouri M, Truong S, Ghaffari M, Adomat HH, Corey E, Cox ME, Li N, Guns ES, Yenki P, Pham S, Buttyan R (2016). "Paracrine Sonic Hedgehog Signaling Contributes Significantly to Acquired Steroidogenesis in the Prostate Tumor Microenvironment". International Journal of Cancer. 140 (2): 358–369. PMID 27672740. doi:10.1002/ijc.30450.
  30. Lichtenthaler HK (Jun 1999). "The 1-deoxy-d-xylulose-5-phosphate pathway of isoprenoid biosynthesis in plants". Annual Review of Plant Physiology and Plant Molecular Biology. 50: 47–65. PMID 15012203. doi:10.1146/annurev.arplant.50.1.47.
  31. Witchel SF, Azziz R (2010). "Nonclassic congenital adrenal hyperplasia". Int J Pediatr Endocrinol. 2010: 625105. PMC 2910408Freely accessible. PMID 20671993. doi:10.1155/2010/625105.
  32. Pikuleva IA (Dec 2006). "Cytochrome P450s and cholesterol homeostasis". Pharmacology & Therapeutics. 112 (3): 761–73. PMID 16872679. doi:10.1016/j.pharmthera.2006.05.014.
  33. Zollner G, Marschall HU, Wagner M, Trauner M (2006). "Role of nuclear receptors in the adaptive response to bile acids and cholestasis: pathogenetic and therapeutic considerations". Molecular Pharmaceutics. 3 (3): 231–51. PMID 16749856. doi:10.1021/mp060010s.
  34. Kliewer SA, Goodwin B, Willson TM (Oct 2002). "The nuclear pregnane X receptor: a key regulator of xenobiotic metabolism". Endocrine Reviews. 23 (5): 687–702. PMID 12372848. doi:10.1210/er.2001-0038.
  35. Steimer T. "Steroid Hormone Metabolism". WHO Collaborating Centre in Education and Research in Human Reproduction. Geneva Foundation for Medical Education and Research.
  36. 1 2 "Russell Marker Creation of the Mexican Steroid Hormone Industry". International Historic Chemical Landmark. American Chemical Society.
  37. 1 2 Makin HL, Honor JW, Shackleton CH, Griffiths WJ (2010). "General methods for the extraction, purification, and measurement of steroids by chromatography and mass spectrometry". In Makin HL, Gower DB. Steroid analysis. Dordrecht; New York: Springer. pp. 163–282. ISBN 978-1-4020-9774-4.
  38. Conner AH, Nagaoka M, Rowe JW, Perlman D (Aug 1976). "Microbial conversion of tall oil sterols to C19 steroids" (PDF). Applied and Environmental Microbiology. 32 (2): 310–1. PMC 170056Freely accessible. PMID 987752.
  39. Wang F-Q, Yao K, Wei D-Z. "From Soybean Phytosterols to Steroid Hormones, Soybean and Health". In El-Shemy H. Soybean and Health. InTech. ISBN 978-953-307-535-8. doi:10.5772/18808.
  40. 1 2 Hesselink PG, Vliet Sv, Vries Hd, Witholt B (1989). "Optimization of steroid side chain cleavage by Mycobacterium sp. in the presence of cyclodextrins". Enzyme and Microbial Technology. 11 (7): 398–404. doi:10.1016/0141-0229(89)90133-6.
  41. 1 2 3 Sandow J, Scheiffele E, Haring M, Neef G, Prezewowsky K, Stache U (2000). "Hormones". Ullmann's Encyclopedia of Industrial Chemistry. ISBN 3527306730. doi:10.1002/14356007.a13_089.
  42. Leigh HM, Meister PD, Weintraub A, Reineke LM, Eppstein SH, Murray HC, Peterson DH (1952). "Microbiological Transformations of Steroids.1 I. Introduction of Oxygen at Carbon-11 of Progesterone". Journal of the American Chemical Society. 73 (23): 5933–5936. doi:10.1021/ja01143a033.
  43. Capek M, Oldrich H, Alois C (1966). Microbial Transformations of Steroids. Prague: Academia Publishing House of Czechoslovak Academy of Sciences. ISBN 9789401176057. doi:10.1007/978-94-011-7603-3.
  44. Marker RE, Rohrmann E (1939). "Sterols. LXXXI. Conversion of Sarsasa-Pogenin to Pregnanedial--3(α),20(α)". Journal of the American Chemical Society. 61 (12): 3592–3593. doi:10.1021/ja01267a513.
  45. "The Nobel Prize in Chemistry 1927". The Nobel Foundation.
  46. "The Nobel Prize in Chemistry 1928". The Nobel Foundation.
  47. "The Nobel Prize in Chemistry 1939". The Nobel Foundation.
  48. "The Nobel Prize in Physiology or Medicine 1950". The Nobel Foundation.
  49. "The Nobel Prize in Chemistry 1965". The Nobel Foundation.
  50. "The Nobel Prize in Chemistry 1969". The Nobel Foundation.
  51. "The Nobel Prize in Chemistry 1975". The Nobel Foundation.

Further reading

This article is issued from Wikipedia. The text is licensed under Creative Commons - Attribution - Sharealike. Additional terms may apply for the media files.