Synthesis of 4'-C-(Aminoethyl)thymidine and 4'-C-[(N-Methyl)aminoethyl] Thymidine Nucleosides to Enhance DNA Stability.

Current Protocols Pub Date : 2022-09-01 DOI:10.1002/cpz1.501
Akash Chandela, Hiroki Ueda, Yoshihito Ueno
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Abstract

Antisense oligonucleotide (ASO) therapeutics target the pathogenic mRNA directly and modulate protein expression. Novel chemical modifications help to improve the action of ASOs with better thermal stability and resistance against nucleases. Oligodeoxynucleotides (ODNs) containing 4'-C-(aminoethyl)thymidine modifications exhibit efficient and stable hybridization with complementary DNA as well as RNA strands showing remarkably improved resistance against nucleolytic hydrolysis, which makes them promising candidates for antisense therapeutics. This article describes the synthesis of a novel nucleoside analog, 4'-C-[(N-methyl)aminoethyl]-thymidine (4'-MAE-T), 3, and previously reported 4'-C-aminoethyl-thymidine (4'-AE-T), 2, through a newly designed synthetic route to obtain a high overall yield. This has been established by changing the starting material from thymidine to diacetone-D-glucofuranose and synthesizing the known 4-C-hydroxyethyl pentofuranose. Conversion of the hydroxy group to an azide functional group through Mitsunobu azidation and performing acetolysis, provide the common intermediate 4-C-(2-azidoethyl)-ribofuranose. Subsequent coupling of the thymine nucleobase with the common intermediate under Vorbrüggen glycosylation conditions provides the corresponding modified nucleoside in high yield. It was subjected for conversion of the azide to an amine by Staudinger reaction and 2'-deoxygenation using Barton-McCombie conditions. Debenzylation with Lewis acid and mono-dimethoxytritylation of the 5'-OH afforded a fully protected 3'-OH intermediate for phosphitylation to give the corresponding phosphoramidites. In the case of 4'-MAE-T, benzyloxymethyl protection of the N3 -position and methylation were carried out prior to debenzylation. These phosphoramidite monomers were suitable with conventional oligonucleotide synthesis, and imparted ameliorated nuclease resistance, and competent RNase H activity, suggesting its potential utilization in ASO drugs. © 2022 Wiley Periodicals LLC. Basic Protocol 1: Preparation of 4-C-(2-azidoethyl)-ribofuranose (6) Basic Protocol 2: Synthesis of 4'-C-aminoethyl thymidine phosphoramidite (15) Basic Protocol 3: Synthesis of 4'-C-(N-methyl)aminoethyl thymidine phosphoramidite (20).

提高DNA稳定性的4′- c -(氨基乙基)胸苷和4′- c -[(n -甲基)氨基乙基]胸苷核苷的合成
反义寡核苷酸(ASO)疗法直接靶向致病mRNA并调节蛋白表达。新的化学修饰有助于提高ASOs的作用,具有更好的热稳定性和对核酸酶的抗性。含有4′- c -(氨基乙基)胸苷修饰的寡脱氧核苷酸(ODNs)与互补DNA和RNA链具有高效和稳定的杂交能力,具有显著提高的抗核水解能力,这使它们成为反义治疗的有希望的候选者。本文介绍了一种新的核苷类似物4′- c -[(n -甲基)氨基乙基]-胸腺嘧啶(4′- mae -t), 3和先前报道的4′- c -氨基乙基胸腺嘧啶(4′- ae -t), 2的合成方法,以获得较高的总收率。这是通过将起始原料从胸腺嘧啶改为二丙酮- d -葡萄糖呋喃糖并合成已知的4- c -羟乙基戊呋喃糖来确定的。通过Mitsunobu叠氮化将羟基转化为叠氮化物官能团并进行乙酰解,得到常见的中间体4-C-(2-叠氮乙基)-核糖呋喃糖。随后在vorbr根糖基化条件下将胸腺嘧啶核碱基与常见中间体偶联,得到相应的高收率修饰核苷。通过Staudinger反应和Barton-McCombie条件下的2′脱氧将叠氮化物转化为胺。用Lewis酸脱苯和5'-OH的单二甲氧基三甲基化为磷酸化提供了完全保护的3'-OH中间体,从而得到相应的磷酰胺。在4'-MAE-T的情况下,在去苄基化之前进行了N3位置的苄氧甲基保护和甲基化。这些磷酸酰胺单体适合于传统的寡核苷酸合成,并具有改善的核酸酶抗性和活性,表明其在ASO药物中的潜在应用。©2022 Wiley期刊有限责任公司基本方案1:4- c -(2-叠氮乙基)-核糖呋喃糖的制备(6)基本方案2:4'- c -氨基乙基胸苷磷酸的合成(15)基本方案3:4'- c -(n -甲基)氨基乙基胸苷磷酸的合成(20)。
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