Stealth nucleosides: mode of action and potential use in the treatment of viral diseases

Riboviruses and retroviruses have been shown to spontaneously mutate at an extraordinarily high rate. While this genetic diversity allows viral subpopulations to escape conventional antivirals, it also has a cost. Indeed, this high mutation rate results in the synthesis of many defective virions. St...

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Bibliographic Details
Published in:BioDrugs : clinical immunotherapeutics, biopharmaceuticals, and gene therapy biopharmaceuticals, and gene therapy, 2003-01, Vol.17 (3), p.169-177
Main Author: Daifuku, Richard
Format: Article
Language:English
Subjects:
Antiviral Agents - pharmacology
Antiviral Agents - therapeutic use
DNA Viruses - drug effects
DNA Viruses - genetics
DNA, Viral - genetics
Drug Resistance, Viral
Genome, Viral
Hepatitis B - drug therapy
Hepatitis B - virology
Hepatitis C - drug therapy
Hepatitis C - virology
HIV Infections - drug therapy
HIV Infections - virology
Humans
Mutagenesis
Nucleosides - pharmacology
Nucleosides - therapeutic use
Retroviridae - drug effects
Retroviridae - genetics
RNA Viruses - drug effects
RNA Viruses - genetics
RNA, Viral - genetics
Smallpox - drug therapy
Smallpox - virology
Virus Replication
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Summary:Riboviruses and retroviruses have been shown to spontaneously mutate at an extraordinarily high rate. While this genetic diversity allows viral subpopulations to escape conventional antivirals, it also has a cost. Indeed, this high mutation rate results in the synthesis of many defective virions. Stealth nucleosides are nucleoside analogues that are designed to increase the already high spontaneous mutation rate of viruses to the point where the virus cannot further replicate, a process known as "lethal mutagenesis". Rather than causing chain termination and attempting to immediately halt viral replication, as with conventional nucleoside reverse transcriptase inhibitors (NRTI), stealth nucleosides are incorporated into the viral genome during replication and, by mispairing, cause mutations to the viral genome. These mutations affect all viral proteins and cumulatively, over a number of replication cycles, are lethal to the virus. There are two distinct stealth nucleoside platforms: DNA stealth nucleosides and RNA stealth nucleosides. DNA stealth nucleosides are currently being screened for activity against HIV and may have activity against hepatitis B virus and smallpox virus, with the clinical lead DNA stealth nucleoside demonstrating activity in the low nanomolar range. In addition, DNA stealth nucleosides have been shown to be able to effectively treat NRTI-resistant HIV strains in vitro, which is not surprising given that the two principal modes of resistance (low affinity of reverse transcriptase for a modified sugar or pyrophosphorolysis) should not be applicable to DNA stealth nucleosides. RNA stealth nucleosides are being developed for the treatment of ribovirus infections, and particularly hepatitis C virus infection. RNA stealth nucleosides are selected for their broad spectrum of antiviral activity, and current lead RNA stealth nucleosides have potency in the same range as ribavirin.
ISSN:1173-8804
DOI:10.2165/00063030-200317030-00003