Design, Synthesis, and Biological Evaluation of Modified Acyclic Fleximer Nucleoside Analogues
Loading...
Links to Files
Permanent Link
Author/Creator
Author/Creator ORCID
Date
2024/01/01
Type of Work
Department
Chemistry & Biochemistry
Program
Chemistry
Citation of Original Publication
Rights
This item may be protected under Title 17 of the U.S. Copyright Law. It is made available by UMBC for non-commercial research and education. For permission to publish or reproduce, please see http://aok.lib.umbc.edu/specoll/repro.php or contact Special Collections at speccoll(at)umbc.edu
Distribution Rights granted to UMBC by the author.
Access limited to the UMBC community. Item may possibly be obtained via Interlibrary Loan thorugh a local library, pending author/copyright holder's permission.
Distribution Rights granted to UMBC by the author.
Access limited to the UMBC community. Item may possibly be obtained via Interlibrary Loan thorugh a local library, pending author/copyright holder's permission.
Abstract
As the SARS-CoV-2 pandemic left lingering effects worldwide, it remains clear there is a need for the development of broad-spectrum antiviral therapeutics to not only help fight the pandemic at hand but help fight future pandemics to come. With this in mind nucleos(t)ides have had a rich history as antivirals. A commonly employed modification is the use of an acyclic sugar (lack of 2’ and/or 3’ carbons on the sugar moiety), such as that found in Acyclovir (ACV), an FDA-approved drug for herpes simplex virus or the FDA-approved drug Cidofovir (CDV) for CMV retinitis. Research in the Seley-Radtke group focuses on investigating nucleos(t)ide analogues known as “fleximers”, which feature a purine nucleobase “split” into its imidazole and pyrimidine moieties via a carbon-carbon single bond, thus introducing flexibility to the nucleobase. This novel design has endowed the fleximer analogues with potent activity not seen in the rigid parent nucleosides. Combining the acyclic sugar, with the fleximer technology produced a series of first-generation, doubly flexible Flex-ACV analogues. Some of these analogues have exhibited activity against filoviruses, flaviviruses, and coronaviruses. Given the broad-spectrum activity exhibited by these fleximers, optimization of previously synthesized Flex-ACV analogues was carried out for further investigation into the biological effects of these nucleosides. The first-generation Flex-ACV nucleosides were synthesized using modern organic chemistry techniques such as various cross-coupling methods, as well as microwave assisted chemistry. Synthesis of various monophosphate and triphosphate analogues allowed for elucidation of the metabolism and mechanism of action of the first-generation analogues. A new series of Flex-ACV analogues that feature a bond between carbon 5 of imidazole and carbon 5 of the pyrimidine moiety have been designed and synthesized. The newly designed analogues are of interest to compare them to the typical proximal fleximer design and evaluate their antiviral activity as well as the potential to reach new residues in a viral enzyme binding pocket. Overall, the flexible acyclic nucleosides continue to show broad-spectrum antiviral activity and have the potential to become an antiviral therapeutic.