Abstract
In a previous study the small molecule SJP-L-5 that inhibits HIV replication, has been shown to block uncoating of the viral capsid. Continued study showed that SJP-L-5 might hinder HIV capsid uncoating by blocking the completion of reverse transcription. However, to date, the mechanism has not been fully elucidated. Here, the effects of SJP-L-5 for reverse transcription were explored via quantitative PCR, DIG-labelled ELISA, fluorescent resonance energy transfer, and Southern blot assays. We also analyzed the resistance profile of this compound against reverse transcriptase. Our results show that SJP-L-5 preferentially inhibits PPT primed plus-strand DNA synthesis (EC50 = 13.4 ± 3.0 μM) over RNA primed minus-strand DNA synthesis (EC50 > 3,646 μM), resulting in formation of five segmented plus-strand DNA and loss of HIV DNA flap, suggesting failure of both nuclear import and integration. Moreover, resistance study evidenced that SJP-L-5 requires the amino acid residues Val108 and Tyr181 to exert an inhibitory effect. These results indicate SJP-L-5 as a new non-nucleoside reverse transcriptase inhibitor that inhibits HIV-1 polypurine tract primed plus-strand DNA synthesis, initiating HIV-1 down-stream plus-strand DNA synthesis at multiple sites under drug pressure.
Highlights
Retroviruses are single-stranded RNA viruses that infect eukaryotic cells
The synthesis of the minus-strand DNA is initiated by a tRNA primer, which binds to the primer-binding site (PBS) near the 5′ end of the viral genomic RNA
Initiation of reverse transcription (RT) is conducted by reverse transcriptase (RTase) RNA-dependent DNA polymerization (RDDP) activity from the tRNA primer, and the synthesis of -sssDNA is one of the first products of this process[16]
Summary
Retroviruses (i.e., human immunodeficiency virus, HIV) are single-stranded RNA viruses that infect eukaryotic cells. RT is a complex process in which reverse transcriptase (RTase) has three functions and makes two jumps[2] These three RTase functions include: (1) RNA-dependent DNA polymerization (RDDP) activity, converting single-stranded viral RNA to minus DNA; (2) DNA-dependent DNA polymerization (DDDP) activity, converting minus DNA to plus DNA; (3) RNase H activity, digesting RNA from RNA/DNA hybrids[3]. Plus DNA of the HIV genome is discrete and holds a triple DNA structure in the center that is essential for importing the pre-integrated complex into the nucleus[5]. This DNA flap is a potential target of anti-HIV drugs; such inhibitors are rarely reported. We hypothesize that SJP-L-5 inhibits the viral plus-strand DNA synthesis by hindering full-length plus-strand DNA maturation
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