Enzymatic Desymmetrization of 19‐nor‐Vitamin D3 A‐Ring Synthon Precursor: Synthesis, Structure Elucidation, and Biological Activity of 1α,25‐Dihydroxy‐3‐epi‐19‐nor‐vitamin D3 and 1β,25‐Dihydroxy‐19‐nor‐vitamin D3

In a search for novel vitamin D derivatives of potential therapeutic value, structurally simple but synthetically challenging A‐ring epimers of the 19‐nor‐Calcitriol [19‐nor‐1α,25‐(OH)2‐D3] at C1 and C3 were efficiently synthesized. Both analogues (1‐epi‐ and 3‐epi‐19‐nor‐Calcitriol) were obtained t...

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Bibliographic Details
Published in:Advanced synthesis & catalysis 2018-07, Vol.360 (14), p.2762-2772
Main Authors: González‐García, Tania, Verstuyf, Annemieke, Verlinden, Lieve, Fernández, Susana, Ferrero, Miguel
Format: Article
Language:English
Subjects:
19-nor analogues
A-Ring modified analogues
Affinity
Biological activity
Calcitriol
Critical point
Derivatives
Enzymatic desymmetrization
NMR spectroscopy
Proteins
Spectrum analysis
Synthesis
Vitamin D
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Summary:In a search for novel vitamin D derivatives of potential therapeutic value, structurally simple but synthetically challenging A‐ring epimers of the 19‐nor‐Calcitriol [19‐nor‐1α,25‐(OH)2‐D3] at C1 and C3 were efficiently synthesized. Both analogues (1‐epi‐ and 3‐epi‐19‐nor‐Calcitriol) were obtained through a convergent synthesis starting from cis,cis‐1,3,5‐cyclohexanetriol and the protected 25‐hydroxy Grundmann′s ketone. After Julia‐Kocienski coupling of the corresponding C,D‐ring/side chain sulfone fragment with the A‐ring ketone moiety, both vitamin D analogues were isolated. The critical point was how to determine the structural configuration of both diastereoisomers since similar 1H NMR spectra were observed. For that, a biocatalytic approach was crucial in the synthesis of orthogonally protected derivatives. NMR spectroscopy allows the unambiguous identification of these compounds and as a result the structural elucidation of the desired vitamin D diastereomeric analogues. Affinity studies demonstrated that these 1,25‐19‐nor analogues have a very low affinity for the vitamin D receptor compared with 1α,25‐dihydroxyvitamin D3 or 1α,25‐dihydroxy‐19‐nor‐vitamin D3. In addition, these analogues have a lower binding affinity for the human vitamin D binding protein than the natural hormone. In vitro cell culture studies revealed that synthesized analogues were less active than 1α,25‐dihydroxyvitamin D3 in inhibiting cell proliferation.
ISSN:1615-4150
1615-4169
DOI:10.1002/adsc.201800481