Abstract
Monitoring of nucleic acid intermediates during virus replication provides insights into the effects and mechanisms of action of antiviral compounds and host cell proteins on viral DNA synthesis. Here we address the lack of a cell-based, high-coverage, and high-resolution assay that is capable of defining retroviral reverse transcription intermediates within the physiological context of virus infection. The described method captures the 3'-termini of nascent complementary DNA (cDNA) molecules within HIV-1 infected cells at single nucleotide resolution. The protocol involves harvesting of whole cell DNA, targeted enrichment of viral DNA via hybrid capture, adaptor ligation, size fractionation by gel purification, PCR amplification, deep sequencing, and data analysis. A key step is the efficient and unbiased ligation of adaptor molecules to open 3'-DNA termini. Application of the described method determines the abundance of reverse transcripts of each particular length in a given sample. It also provides information about the (internal) sequence variation in reverse transcripts and thereby any potential mutations. In general, the assay is suitable for any questions relating to DNA 3'-extension, provided that the template sequence is known.
Highlights
In order to dissect and understand viral replication fully, increasingly refined techniques that capture replication intermediates are required
The technique described in this article was applied to a wider study to address the mechanisms underlying inhibition of human immunodeficiency virus 1 (HIV-1) reverse transcription by the antiretroviral human protein APOBEC3G (A3G)[6]
Increasing levels of A3G reduce the total read number reflecting the inhibitory effect of A3G on reverse transcriptase (RT) mediated complementary DNA (cDNA) synthesis previously described and measured by qPCR6,13,21,22
Summary
In order to dissect and understand viral replication fully, increasingly refined techniques that capture replication intermediates are required. To date, monitoring of HIV-1 RT progression in infected cells has primarily been accomplished by measuring reverse transcription products of various length with quantitative PCR (qPCR) using primer-probe sets that uniquely measure shorter or longer (early and late, respectively) cDNA products[12,13,14]. While this qPCR approach is appropriate to determine intrinsic efficiencies of the reverse transcription process in cellular systems, the output is of relatively low resolution, with no sequence information being derived. NOTE: Please refer to the Table of Materials for specific reagents and equipment used in this protocol
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