Researchers find out how to solve structure of immune-evading HIV protein complex
T
he viral infectivity factor (Vif) of the HIV-1 virus can inhibit cellular defences. Cryo-electron microscopy has now been used by OIST researchers Prof. Matthias Wolf and Dr Takahide Kouno as well as a global team of collaborators to discover the atomic structure of the APOBEC3G-Vif complex.
"APOBEC3G (A3G) is a key component of the human innate immune system to defend against invading viruses, getting a ride inside budding virions like in a Trojan horse so that it can modify and disable viral DNA after reverse transcription in infected cells," Prof. Wolf, the senior author of the study and who leads the OIST Molecular Cryo-Electron Microscopy Unit explains. "But HIV-1 has evolved a counteraction mechanism in the form of its Vif protein, which inhibits this process by binding to and degrading A3G, leading to successful amplification of infectious viral particles."
A unique aspect of their study is the first demonstration that this complex formation is mediated by specific RNA sequences, even though single-stranded DNA is the substrate of degradation by A3G. Their protein construct was optimized for higher solubility and could replicate the degradation pathway by A3G ubiquitination (a process that involves the transfer of ubiquitin polyubiqitination to a target protein and is important in many physiological functions) in vitro.
The work identified specific interactions between protein and the RNA ligand, which may be targeted with drugs for future antiviral therapies against HIV/AIDS that inhibit the A3G-Vif interaction.
✔️ Researchers find out how to solve structure of immune-evading HIV protein complex
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