Synthesis of 19-norcalcitriol analogs with elongated side chain.

Pronounced biological potency of 19-norvitamin D compounds as well as interesting biological action of the vitamin D analogs possessing elongated side chains encouraged us to expand the scope of our structure-activity studies to encompass such modifications of the 1α,25-(OH)2D3 (calcitriol) molecule. The aim of our studies was the synthesis of calcitriol analog, designed on the basis of results of molecular modeling and docking experiments, and characterized by a presence of a long, nitrogen-containing substituent attached to carbon 26, and an exomethylene moiety transferred from C-10 to C-2. The convergent synthesis of such 19-norcalcitriol compound, described in this communication, consisted of the preparation and combining four building blocks. The crucial point of the synthesis, coupling of the known A-ring phosphine oxide and the synthesized Grundmann ketone analog, was achieved using Wittig-Horner protocol. It provided the protected analog of 1α,25-dihydroxy-2-methylene-19-norvitamin D3 which was further transformed into the target compound.

Design, synthesis and biological properties of seco-d-ring modified 1α,25-dihydroxyvitamin D3 analogues.

As a continuation of our efforts directed to the structure-activity relationship studies of vitamin D compounds, we present in this paper the synthesis of new analogues of 1α,25-(OH)2D3 characterized by numerous structural modifications, especially a cleaved D ring. Total synthesis of the CD fragment required for the construction of the target vitamins was based on the Stork approach. The structure of the key intermediate - bicyclic hydroxy lactone - was established by crystallographic and electronic circular dichroism (ECD) spectral analysis. Following the attachment of the hydroxyalkyl side chain, the formed D-seco Grundmann ketone was subjected to Wittig-Horner coupling with the corresponding A-ring phosphine oxides providing two desired D-seco analogues of 19-nor-1α,25-(OH)2D3, one without a substituent at C-2 and the other possessing a 2-exomethylene group. Both compounds were biologically tested and the latter was found to be more active in in vitro tests. Despite so many structural changes introduced in its structure, the biological activity of the 2-methylene analogue approached that of the natural hormone. The synthesized D-seco vitamins, however, proved to be inactive on bone and intestine in vivo.