Isolation and characterization of a small antiretroviral molecule affecting HIV-1 capsid morphology
Author
Summary, in English
Background
Formation of an HIV-1 particle with a conical core structure is a prerequisite for the subsequent infectivity of the virus particle. We have previously described that glycineamide (G-NH2) when added to the culture medium of infected cells induces non-infectious HIV-1 particles with aberrant core structures.
Results
Here we demonstrate that it is not G-NH2 itself but a metabolite thereof that affects HIV-1 infectivity and capsid assembly. The conversion of G-NH2 to its antiviral metabolite is catalyzed by an enzyme present in bovine and porcine but surprisingly not in human serum. Structure determination by NMR suggested that the active G-NH2 metabolite was α-hydroxyglycineamide (α-HGA). Chemically synthesized α-HGA inhibited HIV-1 replication to the same degree as G-NH2, unlike a number of other synthesized analogues of G-NH2 which had
no effect on HIV-1 replication. Comparisons by capillary electrophoresis and HPLC of the metabolite with the chemically synthesized α-HGA further confirmed that the antiviral GNH2-metabolite indeed was α-HGA.
Conclusions
α-HGA has an unusually simple structure and a novel mechanism of antiviral action. Thus, α-HGA could be a lead for new antiviral substances belonging to a new class of anti-HIV drugs, i.e. capsid assembly inhibitors.
Formation of an HIV-1 particle with a conical core structure is a prerequisite for the subsequent infectivity of the virus particle. We have previously described that glycineamide (G-NH2) when added to the culture medium of infected cells induces non-infectious HIV-1 particles with aberrant core structures.
Results
Here we demonstrate that it is not G-NH2 itself but a metabolite thereof that affects HIV-1 infectivity and capsid assembly. The conversion of G-NH2 to its antiviral metabolite is catalyzed by an enzyme present in bovine and porcine but surprisingly not in human serum. Structure determination by NMR suggested that the active G-NH2 metabolite was α-hydroxyglycineamide (α-HGA). Chemically synthesized α-HGA inhibited HIV-1 replication to the same degree as G-NH2, unlike a number of other synthesized analogues of G-NH2 which had
no effect on HIV-1 replication. Comparisons by capillary electrophoresis and HPLC of the metabolite with the chemically synthesized α-HGA further confirmed that the antiviral GNH2-metabolite indeed was α-HGA.
Conclusions
α-HGA has an unusually simple structure and a novel mechanism of antiviral action. Thus, α-HGA could be a lead for new antiviral substances belonging to a new class of anti-HIV drugs, i.e. capsid assembly inhibitors.
Department/s
Publishing year
2009
Language
English
Publication/Series
Retrovirology
Volume
6
Issue
34
Full text
Document type
Journal article
Publisher
BioMed Central (BMC)
Topic
- Medical Engineering
Status
Published
ISBN/ISSN/Other
- ISSN: 1742-4690