Hsiao-Wei Liu scite author profile

Reverse transcription of the HIV-1 RNA genome involves several complex nucleic acid rearrangement steps that are catalyzed by the HIV-1 nucleocapsid protein (NC), including for example, the annealing of the transactivation response (TAR) region of the viral RNA to the complementary region (TAR DNA) in minus-strand strong-stop DNA. We report herein single-molecule fluorescence resonance energy transfer measurements on single immobilized TAR DNA hairpins and hairpin mutants complexed with NC (i.e., TAR DNA/NC). Using this approach we have explored the conformational distribution and dynamics of the hairpins in the presence and absence of NC protein. The data demonstrate that NC shifts the equilibrium secondary structure of TAR DNA hairpins from a fully "closed" conformation to essentially one specific "partially open" conformation. In this specific conformation, the two terminal stems are "open" or unwound and the other stems are closed. This partially open conformation is arguably a key TAR DNA intermediate in the NC-induced annealing mechanism of TAR DNA.

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Insights on the role of nucleic acid/protein interactions in chaperoned nucleic acid rearrangements of HIV-1 reverse transcription

Liu

Zeng

Landes

et al. 2007

Proc. Natl. Acad. Sci. U.S.A.

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HIV-1 reverse transcription requires several nucleic acid rearrangement steps that are ''chaperoned'' by the nucleocapsid protein (NC), including minus-strand transfer, in which the DNA transactivation response element (TAR) is annealed to the complementary TAR RNA region of the viral genome. These various rearrangement processes occur in NC bound complexes of specific RNA and DNA structures. A major barrier to the investigation of these processes in vitro has been the diversity and heterogeneity of the observed nucleic acid/protein assemblies, ranging from small complexes of only one or two nucleic acid molecules all the way up to large-scale aggregates comprised of thousands of NC and nucleic acid molecules. Herein, we use a flow chamber approach involving rapid NC/nucleic acid mixing to substantially control aggregation for the NC chaperoned irreversible annealing kinetics of a model TAR DNA hairpin sequence to the complementary TAR RNA hairpin, i.e., to form an extended duplex. By combining the flow chamber approach with a broad array of fluorescence single-molecule spectroscopy (SMS) tools (FRET, molecule counting, and correlation spectroscopy), we have unraveled the complex, heterogeneous kinetics that occur during the course of annealing. The SMS results demonstrate that the TAR hairpin reactant is predominantly a single hairpin coated by multiple NCs with a dynamic secondary structure, involving equilibrium between a ''Y'' shaped conformation and a closed one. The data further indicate that the nucleation of annealing occurs in an encounter complex that is formed by two hairpins with one or both of the hairpins in the ''Y'' conformation.HIV-1 nucleocapsid protein ͉ nucleic acid aggregation ͉ transactivation response element DNA/RNA annealing ͉ wild-type (WT)

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Probing nucleation, reverse annealing, and chaperone function along the reaction path of HIV-1 single-strand transfer

Zeng

Liu

Landes

et al. 2007

Proc. Natl. Acad. Sci. U.S.A.

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Reverse transcription of the HIV-1 genome involves several nucleic acid rearrangement steps that are catalyzed (chaperoned) by the nucleocapsid protein (NC), including the annealing of the transactivation response region (TAR) RNA of the genome to the complementary sequence (TAR DNA) in minus-strand strong-stop DNA. It has been extremely challenging to obtain unambiguous mechanistic details on the annealing process at the molecular level because of the kinetic involvement of a complex and heterogeneous set of nucleic acid/protein complexes of variable structure and variable composition. Here, we investigate the in vitro annealing mechanism using a multistep single-molecule spectroscopy kinetic method. In this approach, an immobilized hairpin is exposed to a multistep programmed concentration sequence of NC, model complementary targeted-oligonucleotides, and buffer-only solutions. The sequence controllably ''drags'' single immobilized TAR hairpins among the kinetic stable states of the reaction mechanism; i.e., reactants, intermediates, and products. This single-molecule spectroscopy method directly probes kinetic reversibility and the chaperone (catalytic) role of NC at various stages along the reaction sequence, giving access to previously inaccessible kinetic processes and rate constants. By employing target oligonucleotides for specific TAR regions, we kinetically trap and investigate structural models for putative nucleation complexes for the annealing process. The new results lead to a more complete and detailed understanding of the ability of NC to promote nucleic acid/nucleic acid rearrangement processes. This includes information on the ability of NC to chaperone ''reverse annealing'' in single-strand transfer and the first observation of partially annealed, conformational substates in the annealing mechanism.HIV-1 nucleocapsid protein ͉ transactivation response element

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Single-Molecule Study of the Inhibition of HIV-1 Transactivation Response Region DNA/DNA Annealing by Argininamide

et al. 2007

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Single-molecule spectroscopy was used to examine how a model inhibitor of HIV-1, argininamide, modulates the nucleic acid chaperone activity of the nucleocapsid protein (NC) in the minus-strand transfer step of HIV-1 reverse transcription, in vitro. In minus-strand transfer, the transactivation response region (TAR) RNA of the genome is annealed to the complementary "TAR DNA" generated during minus-strand strong-stop DNA synthesis. Argininamide and its analogs are known to bind to the hairpin bulge region of TAR RNA as well as to various DNA loop structures, but its ability to inhibit the strand transfer process has only been implied. Here, we explore how argininamide modulates the annealing kinetics and secondary structure of TAR DNA. The studies reveal that the argininamide inhibitory mechanism involves a shift of the secondary structure of TAR, away from the NC-induced "Y" form, an intermediate in reverse transcription, and toward the free closed or "C" form. In addition, more potent inhibition of the loop-mediated annealing pathway than stem-mediated annealing is observed. Taken together, these data suggest a molecular mechanism wherein argininamide inhibits NC-facilitated TAR RNA/DNA annealing in vitro by interfering with the formation of key annealing intermediates.

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Hsiao-Wei Liu

Secondary Structure and Secondary Structure Dynamics of DNA Hairpins Complexed with HIV-1 NC Protein

Insights on the role of nucleic acid/protein interactions in chaperoned nucleic acid rearrangements of HIV-1 reverse transcription

Probing nucleation, reverse annealing, and chaperone function along the reaction path of HIV-1 single-strand transfer

Single-Molecule Study of the Inhibition of HIV-1 Transactivation Response Region DNA/DNA Annealing by Argininamide

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