Human immunodeficiency virus type 1 nucleocapsid protein can prevent self-priming of minus-strand strong stop DNA by promoting the annealing of short oligonucleotides to hairpin sequences

Virion-associated, host-derived DHX9/RNA helicase A enhances the processivity of HIV-1 reverse transcriptase on genomic RNA

DHX9/RNA helicase A (RHA) is a host RNA helicase that participates in many critical steps of the HIV-1 life cycle. It co-assembles with the viral RNA genome into the capsid core. Virions deficient in RHA are less infectious as a result of reduced reverse transcription efficiency, demonstrating that the virion-associated RHA promotes reverse transcription before the virion gains access to the new host's RHA. Here, we quantified reverse-transcription intermediates in HIV-1-infected T cells to clarify the mechanism by which RHA enhances HIV-1 reverse transcription efficiency. Consistently, purified recombinant human RHA promoted reverse transcription efficiency under in vitro conditions that mimic the early reverse transcription steps prior to capsid core uncoating. We did not observe RHA-mediated structural remodeling of the tRNALys3-viral RNA-annealed complex. RHA did not enhance the DNA synthesis rate until incorporation of the first few nucleotides, suggesting that RHA participates primarily in the elongation phase of reverse transcription. Pre-steady-state and steady-state kinetic studies revealed that RHA has little impact on the kinetics of single-nucleotide incorporation. Primer extension assays performed in the presence of trap dsDNA disclosed that RHA enhances the processivity of HIV-1 reverse transcriptase (RT). The biochemical assays used here effectively reflected and explained the low RT activity in HIV-1 virions produced from RHA-depleted cells. Moreover, RT activity in our assays indicated that RHA in HIV-1 virions is required for the efficient catalysis of (-)cDNA synthesis during viral infection before capsid uncoating. Our study identifies RHA as a processivity factor of HIV-1 RT.

Retroviral nucleocapsid proteins and DNA strand transfers

An infectious retroviral particle contains 1000-1500 molecules of the nucleocapsid protein (NC) that cover the diploid RNA genome. NC is a small zinc finger protein that possesses nucleic acid chaperone activity that enables NC to rearrange DNA and RNA molecules into the most thermodynamically stable structures usually those containing the maximum number of base pairs. Thanks to the chaperone activity, NC plays an essential role in reverse transcription of the retroviral genome by facilitating the strand transfer reactions of this process. In addition, these reactions are involved in recombination events that can generate multiple drug resistance mutations in the presence of anti-HIV-1 drugs. The strand transfer reactions rely on base pairing of folded DNA/RNA structures. The molecular mechanisms responsible for NC-mediated strand transfer reactions are presented and discussed in this review. Antiretroviral strategies targeting the NC-mediated strand transfer events are also discussed.

Mechanistic differences between HIV-1 and SIV nucleocapsid proteins and cross-species HIV-1 genomic RNA recognition

BACKGROUND

The nucleocapsid (NC) domain of HIV-1 Gag is responsible for specific recognition and packaging of genomic RNA (gRNA) into new viral particles. This occurs through specific interactions between the Gag NC domain and the Psi packaging signal in gRNA. In addition to this critical function, NC proteins are also nucleic acid (NA) chaperone proteins that facilitate NA rearrangements during reverse transcription. Although the interaction with Psi and chaperone activity of HIV-1 NC have been well characterized in vitro, little is known about simian immunodeficiency virus (SIV) NC. Non-human primates are frequently used as a platform to study retroviral infection in vivo; thus, it is important to understand underlying mechanistic differences between HIV-1 and SIV NC.

RESULTS

Here, we characterize SIV NC chaperone activity for the first time. Only modest differences are observed in the ability of SIV NC to facilitate reactions that mimic the minus-strand annealing and transfer steps of reverse transcription relative to HIV-1 NC, with the latter displaying slightly higher strand transfer and annealing rates. Quantitative single molecule DNA stretching studies and dynamic light scattering experiments reveal that these differences are due to significantly increased DNA compaction energy and higher aggregation capability of HIV-1 NC relative to the SIV protein. Using salt-titration binding assays, we find that both proteins are strikingly similar in their ability to specifically interact with HIV-1 Psi RNA. In contrast, they do not demonstrate specific binding to an RNA derived from the putative SIV packaging signal.

CONCLUSIONS

Based on these studies, we conclude that (1) HIV-1 NC is a slightly more efficient NA chaperone protein than SIV NC, (2) mechanistic differences between the NA interactions of highly similar retroviral NC proteins are revealed by quantitative single molecule DNA stretching, and (3) SIV NC demonstrates cross-species recognition of the HIV-1 Psi RNA packaging signal.

Reverse Transcription of Retroviruses and LTR Retrotransposons

The enzyme reverse transcriptase (RT) was discovered in retroviruses almost 50 years ago. The demonstration that other types of viruses, and what are now called retrotransposons, also replicated using an enzyme that could copy RNA into DNA came a few years later. The intensity of the research in both the process of reverse transcription and the enzyme RT was greatly stimulated by the recognition, in the mid-1980s, that human immunodeficiency virus (HIV) was a retrovirus and by the fact that the first successful anti-HIV drug, azidothymidine (AZT), is a substrate for RT. Although AZT monotherapy is a thing of the past, the most commonly prescribed, and most successful, combination therapies still involve one or both of the two major classes of anti-RT drugs. Although the basic mechanics of reverse transcription were worked out many years ago, and the first high-resolution structures of HIV RT are now more than 20 years old, we still have much to learn, particularly about the roles played by the host and viral factors that make the process of reverse transcription much more efficient in the cell than in the test tube. Moreover, we are only now beginning to understand how various host factors that are part of the innate immunity system interact with the process of reverse transcription to protect the host-cell genome, the host cell, and the whole host, from retroviral infection, and from unwanted retrotransposition.

Fold or hold: experimental evolution in vitro

We introduce a system for experimental evolution consisting of populations of short oligonucleotides (Oli populations) evolving in a modified quantitative polymerase chain reaction (qPCR). It is tractable at the genetic, genomic, phenotypic and fitness levels. The Oli system uses DNA hairpins designed to form structures that self-prime under defined conditions. Selection acts on the phenotype of self-priming, after which differences in fitness are amplified and quantified using qPCR. We outline the methodological and bioinformatics tools for the Oli system here and demonstrate that it can be used as a conventional experimental evolution model system by test-driving it in an experiment investigating adaptive evolution under different rates of environmental change.

Zinc finger function of HIV-1 nucleocapsid protein is required for removal of 5'-terminal genomic RNA fragments: a paradigm for RNA removal reactions in HIV-1 reverse transcription

During (-) strong-stop DNA [(-) SSDNA] synthesis, RNase H cleavage of genomic viral RNA generates small 5'-terminal RNA fragments (14-18 nt) that remain annealed to the DNA. Unless these fragments are removed, the minus-strand transfer reaction, required for (-) SSDNA elongation, cannot occur. Here, we describe the mechanism of 5'-terminal RNA removal and the roles of HIV-1 nucleocapsid protein (NC) and RNase H cleavage in this process. Using an NC-dependent system that models minus-strand transfer, we show that the presence of short terminal fragments pre-annealed to (-) SSDNA has no impact on strand transfer, implying efficient fragment removal. Moreover, in reactions with an RNase H(-) reverse transcriptase mutant, NC alone is able to facilitate fragment removal, albeit less efficiently than in the presence of both RNase H activity and NC. Results obtained from novel electrophoretic gel mobility shift and Förster Resonance Energy Transfer assays, which each directly measure RNA fragment release from a duplex in the absence of DNA synthesis, demonstrate for the first time that the architectural integrity of NC's zinc finger (ZF) domains is absolutely required for this reaction. This suggests that NC's helix destabilizing activity (associated with the ZFs) facilitates strand exchange through the displacement of these short terminal RNAs by the longer 3' acceptor RNA, which forms a more stable duplex with (-) SSDNA. Taken together with previously published results, we conclude that NC-mediated fragment removal is linked mechanistically with selection of the correct primer for plus-strand DNA synthesis and tRNA removal step prior to plus-strand transfer. Thus, HIV-1 has evolved a single mechanism for these RNA removal reactions that are critical for successful reverse transcription.

Comparative nucleic acid chaperone properties of the nucleocapsid protein NCp7 and Tat protein of HIV-1

RNA chaperones are proteins able to rearrange nucleic acid structures towards their most stable conformations. In retroviruses, the reverse transcription of the viral RNA requires multiple and complex nucleic acid rearrangements that need to be chaperoned. HIV-1 has evolved different viral-encoded proteins with chaperone activity, notably Tat and the well described nucleocapsid protein NCp7. We propose here an overview of the recent reports that examine and compare the nucleic acid chaperone properties of Tat and NCp7 during reverse transcription to illustrate the variety of mechanisms of action of the nucleic acid chaperone proteins.

The role of Vif oligomerization and RNA chaperone activity in HIV-1 replication

The viral infectivity factor (Vif) is essential for the productive infection and dissemination of HIV-1 in non-permissive cells that involve most natural HIV-1 target cells. Vif counteracts the packaging of two cellular cytidine deaminases named APOBEC3G (A3G) and A3F by diverse mechanisms including the recruitment of an E3 ubiquitin ligase complex and the proteasomal degradation of A3G/A3F, the inhibition of A3G mRNA translation or by a direct competition mechanism. In addition, Vif appears to be an active partner of the late steps of viral replication by participating in virus assembly and Gag processing, thus regulating the final stage of virion formation notably genomic RNA dimerization and by inhibiting the initiation of reverse transcription. Vif is a small pleiotropic protein with multiple domains, and recent studies highlighted the importance of Vif conformation and flexibility in counteracting A3G and in binding RNA. In this review, we will focus on the oligomerization and RNA chaperone properties of Vif and show that the intrinsic disordered nature of some Vif domains could play an important role in virus assembly and replication. Experimental evidence demonstrating the RNA chaperone activity of Vif will be presented.

Characterization of the inhibition mechanism of HIV-1 nucleocapsid protein chaperone activities by methylated oligoribonucleotides

Since currently available therapies against HIV/AIDS still show important drawbacks, the development of novel anti-HIV treatments is a key issue. We recently characterized methylated oligoribonucleotides (mONs) that extensively inhibit HIV-1 replication in primary T cells at nanomolar concentrations. The mONs were shown to target both HIV-1 reverse transcriptase (RT) and the nucleocapsid protein (NC), which is an essential partner of RT during viral DNA synthesis. To further understand the mechanism of such mONs, we studied by isothermal titration calorimetry and fluorescence-based techniques their NC binding properties and ability to inhibit the nucleic acid chaperone properties of NC. Notably, we investigated the ability of mONs to inhibit the NC-induced destabilization of the HIV-1 cTAR (complementary DNA sequence to TAR [transactivation response element]) stem-loop and the NC-promoted cTAR annealing to its complementary sequence, required at the early stage of HIV-1 viral DNA synthesis. Moreover, we compared the activity of the mONs to that of a number of modified and nonmodified oligonucleotides. Results show that the mONs inhibit NC by a competitive mechanism whereby the mONs tightly bind the NC peptide, mainly through nonelectrostatic interactions with the hydrophobic platform at the top of the NC zinc fingers. Taken together, these results favor the notion that the mONs impair the process of the RT-directed viral DNA synthesis by sequestering NC molecules, thus preventing the chaperoning of viral DNA synthesis by NC. These findings contribute to the understanding of the molecular basis for NC inhibition by mONs, which could be used for the rational design of antiretroviral compounds targeting HIV-1 NC protein.

Inhibition of both HIV-1 reverse transcription and gene expression by a cyclic peptide that binds the Tat-transactivating response element (TAR) RNA

The RNA response element TAR plays a critical role in HIV replication by providing a binding site for the recruitment of the viral transactivator protein Tat. Using a structure-guided approach, we have developed a series of conformationally-constrained cyclic peptides that act as structural mimics of the Tat RNA binding region and block Tat-TAR interactions at nanomolar concentrations in vitro. Here we show that these compounds block Tat-dependent transcription in cell-free systems and in cell-based reporter assays. The compounds are also cell permeable, have low toxicity, and inhibit replication of diverse HIV-1 strains, including both CXCR4-tropic and CCR5-tropic primary HIV-1 isolates of the divergent subtypes A, B, C, D and CRF01_AE. In human peripheral blood mononuclear cells, the cyclic peptidomimetic L50 exhibited an IC₅₀ ∼250 nM. Surprisingly, inhibition of LTR-driven HIV-1 transcription could not account for the full antiviral activity. Timed drug-addition experiments revealed that L-50 has a bi-phasic inhibition curve with the first phase occurring after HIV-1 entry into the host cell and during the initiation of HIV-1 reverse transcription. The second phase coincides with inhibition of HIV-1 transcription. Reconstituted reverse transcription assays confirm that HIV-1 (−) strand strong stop DNA synthesis is blocked by L50-TAR RNA interactions in-vitro. These findings are consistent with genetic evidence that TAR plays critical roles both during reverse transcription and during HIV gene expression. Our results suggest that antiviral drugs targeting TAR RNA might be highly effective due to a dual inhibitory mechanism.

The HIV-1 transactivator protein (Tat), together with the elongation factor P-TEFb binds to an HIV-1 RNA secondary structure in the 5′-UTRs of nascent viral mRNAs (TAR) and promotes transcription elongation. This process has been an attractive target for drug development but previous inhibitors that bind either Tat or TAR have been plagued by poor inhibition of virus replication, limited cell penetration, and off-target effects. In this article, we describe a series of rationally designed cyclic peptides that block Tat-TAR interactions. L50, the most potent of these compounds, inhibits a wide range of HIV-1 strains from around the world. Remarkably, L50 inhibits two distinct steps in the HIV-1 lifecycle. As expected, L50 inhibits Tat-dependent HIV-1 transcription, but the majority of its anti-HIV activity is due to a block in reverse transcription, i.e. synthesis of the proviral DNA from the RNA genome. L50 inhibition of reverse transcription reveals an important role for TAR RNA during reverse transcription as well as providing one of first examples of a drug with a dual mechanism of action.

Role of HIV-1 nucleocapsid protein in HIV-1 reverse transcription

The HIV-1 nucleocapsid protein (NC) is a nucleic acid chaperone, which remodels nucleic acid structures so that the most thermodynamically stable conformations are formed. This activity is essential for virus replication and has a critical role in mediating highly specific and efficient reverse transcription. NC's function in this process depends upon three properties: (1) ability to aggregate nucleic acids; (2) moderate duplex destabilization activity; and (3) rapid on-off binding kinetics. Here, we present a detailed molecular analysis of the individual events that occur during viral DNA synthesis and show how NC's properties are important for almost every step in the pathway. Finally, we also review biological aspects of reverse transcription during infection and the interplay between NC, reverse transcriptase, and human APOBEC3G, an HIV-1 restriction factor that inhibits reverse transcription and virus replication in the absence of the HIV-1 Vif protein.

Single-molecule stretching studies of RNA chaperones

RNA chaperone proteins play significant roles in diverse biological contexts. The most widely studied RNA chaperones are the retroviral nucleocapsid proteins (NC), also referred to as nucleic acid (NA) chaperones. Surprisingly, the biophysical properties of the NC proteins vary significantly for different viruses, and it appears that HIV-1 NC has optimal NA chaperone activity. In this review we discuss the physical nature of the NA chaperone activity of NC. We conclude that the optimal NA chaperone must saturate NA binding, leading to strong NA aggregation and slight destabilization of all NA duplexes. Finally, rapid kinetics of the chaperone protein interaction with NA is another primary component of its NA chaperone activity. We discuss these characteristics of HIV-1 NC and compare them with those of other NA binding proteins and ligands that exhibit only some characteristics of NA chaperone activity, as studied by single molecule DNA stretching.

Fundamental differences between the nucleic acid chaperone activities of HIV-1 nucleocapsid protein and Gag or Gag-derived proteins: biological implications

The HIV-1 Gag polyprotein precursor has multiple domains including nucleocapsid (NC). Although mature NC and NC embedded in Gag are nucleic acid chaperones (proteins that remodel nucleic acid structure), few studies include detailed analysis of the chaperone activity of partially processed Gag proteins and comparison with NC and Gag. Here we address this issue by using a reconstituted minus-strand transfer system. NC and NC-containing Gag proteins exhibited annealing and duplex destabilizing activities required for strand transfer. Surprisingly, unlike NC, with increasing concentrations, Gag proteins drastically inhibited the DNA elongation step. This result is consistent with "nucleic acid-driven multimerization" of Gag and the reported slow dissociation of Gag from bound nucleic acid, which prevent reverse transcriptase from traversing the template ("roadblock" mechanism). Our findings illustrate one reason why NC (and not Gag) has evolved as a critical cofactor in reverse transcription, a paradigm that might also extend to other retrovirus systems.

The nucleocapsid protein of HIV-1 as a promising therapeutic target for antiviral drugs

The nucleocapsid protein (NCp7) is a major HIV-1 structural protein that plays key roles in viral replication, mainly through its conserved zinc fingers that direct specific interactions with the viral nucleic acids. Owing to its high degree of conservation and critical functions, NCp7 represents a target of choice for drugs that can potentially complement HAART, thus possibly impairing the circulation of drug-resistant HIV-1 strains. Zinc ejectors showing potent antiretroviral activity were developed, but early generations suffered from limited selectively and significant toxicity. Compounds with improved selectivity have been developed and are being explored as topical microbicide candidates. Several classes of molecules inhibiting the interaction of NCp7 with the viral nucleic acids have also been developed. Although small molecules would be more suited for drug development, most molecules selected by screening showed limited antiretroviral activity. Peptides and RNA aptamers appear to be more promising, but the mechanism of their antiretroviral activity remains elusive. Substantial and more concerted efforts are needed to further develop anti-HIV drugs targeting NCp7 and bring them to the clinic.

Inhibition of HIV-1 replication by a bis-thiadiazolbenzene-1,2-diamine that chelates zinc ions from retroviral nucleocapsid zinc fingers

The human immunodeficiency virus type 1 (HIV-1) nucleocapsid p7 (NCp7) protein holds two highly conserved "CCHC" zinc finger domains that are required for several phases of viral replication. Basic residues flank the zinc fingers, and both determinants are required for high-affinity binding to RNA. Several compounds were previously found to target NCp7 by reacting with the sulfhydryl group of cysteine residues from the zinc fingers. Here, we have identified an N,N'-bis(1,2,3-thiadiazol-5-yl)benzene-1,2-diamine (NV038) that efficiently blocks the replication of a wide spectrum of HIV-1, HIV-2, and simian immunodeficiency virus (SIV) strains. Time-of-addition experiments indicate that NV038 interferes with a step of the viral replication cycle following the viral entry but preceding or coinciding with the early reverse transcription reaction, pointing toward an interaction with the nucleocapsid protein p7. In fact, in vitro, NV038 efficiently depletes zinc from NCp7, which is paralleled by the inhibition of the NCp7-induced destabilization of cTAR (complementary DNA sequence of TAR). A chemical model suggests that the two carbonyl oxygens of the esters in this compound are involved in the chelation of the Zn(2+) ion. This compound thus acts via a different mechanism than the previously reported zinc ejectors, as its structural features do not allow an acyl transfer to Cys or a thiol-disulfide interchange. This new lead and the mechanistic study presented provide insight into the design of a future generation of anti-NCp7 compounds.

A succession of mechanisms stimulate efficient reconstituted HIV-1 minus strand strong stop DNA transfer

Donor-acceptor template systems in vitro were designed to test mechanisms of minus strand transfer of human immunodeficiency virus 1 (HIV-1). Donor RNA D199, extending from the 5' end of the HIV-1 genome to the primer binding site (PBS), promoted transfer to only 35% with an acceptor RNA representing the 3' terminal 97 nucleotides, whereas donor RNA D520, including an additional 321 nucleotides 3' of PBS, exhibited 75% transfer. Both donors transferred through an invasion-driven pathway, but transfer was stimulated by the folding structure resulting from the extra segment in D520. In this study, the significance of interaction between the tRNA(lys3) primer and U3 was examined. Measurements utilizing acceptors having or lacking the U3 region complementary with tRNA(lys3) indicated that a tRNA(lys3)-U3 interaction compensated for inefficient acceptor invasion observed with D199. Stimulation presumably occurred because binding to tRNA(lys3) increased the proximity of the acceptor to elongated cDNA, improving transfer to 78% efficiency with D199, and even higher to 85% with D520. The stimulation did not require natural viral sequences but could be achieved by substituting the original U3 sequence with an equal length sequence that binds a different region of tRNA(lys3). Comparison between acceptors sharing the natural region for tRNA(lys3)-U3 interaction but having or lacking the acceptor invasion site demonstrated that tRNA(lys3)-U3 interaction and acceptor invasion cooperate for maximal stimulation. Overall, observations suggest that both proximity and invasion mechanisms are applied successively by HIV-1 for efficient minus strand transfer.

Human T-cell lymphotropic virus type 1 nucleocapsid protein-induced structural changes in transactivation response DNA hairpin measured by single-molecule fluorescence resonance energy transfer

Time-resolved single-molecule fluorescence spectroscopy was used to study the human T-cell lymphotropic virus type 1 (HTLV-1) nucleocapsid protein (NC) chaperone activity compared to that of the human immunodeficiency virus type 1 (HIV-1) NC protein. HTLV-1 NC contains two zinc fingers, each having a CCHC binding motif similar to HIV-1 NC. HIV-1 NC is required for recognition and packaging of the viral RNA and is also a nucleic acid chaperone protein that facilitates nucleic acid restructuring during reverse transcription. Because of similarities in structures between the two retroviruses, we have used single-molecule fluorescence energy transfer to investigate the chaperoning activity of the HTLV-1 NC protein. The results indicate that the HTLV-1 NC protein induces structural changes by opening the transactivation response (TAR) DNA hairpin to an even greater extent than HIV-1 NC. However, unlike HIV-1 NC, HTLV-1 NC does not chaperone the strand-transfer reaction involving TAR DNA. These results suggest that, despite its effective destabilization capability, HTLV-1 NC is not as effective at overall chaperone function as is its HIV-1 counterpart.

Retroviral nucleocapsid proteins display nonequivalent levels of nucleic acid chaperone activity

Human immunodeficiency virus type 1 (HIV-1) nucleocapsid protein (NC) is a nucleic acid chaperone that facilitates the remodeling of nucleic acids during various steps of the viral life cycle. Two main features of NC's chaperone activity are its abilities to aggregate and to destabilize nucleic acids. These functions are associated with NC's highly basic character and with its zinc finger domains, respectively. While the chaperone activity of HIV-1 NC has been extensively studied, less is known about the chaperone activities of other retroviral NCs. In this work, complementary experimental approaches were used to characterize and compare the chaperone activities of NC proteins from four different retroviruses: HIV-1, Moloney murine leukemia virus (MLV), Rous sarcoma virus (RSV), and human T-cell lymphotropic virus type 1 (HTLV-1). The different NCs exhibited significant differences in their overall chaperone activities, as demonstrated by gel shift annealing assays, decreasing in the order HIV-1 approximately RSV > MLV >> HTLV-1. In addition, whereas HIV-1, RSV, and MLV NCs are effective aggregating agents, HTLV-1 NC, which exhibits poor overall chaperone activity, is unable to aggregate nucleic acids. Measurements of equilibrium binding to single- and double-stranded oligonucleotides suggested that all four NC proteins have moderate duplex destabilization capabilities. Single-molecule DNA-stretching studies revealed striking differences in the kinetics of nucleic acid dissociation between the NC proteins, showing excellent correlation between nucleic acid dissociation kinetics and overall chaperone activity.

Nucleocapsid protein function in early infection processes

The role of nucleocapsid protein (NC) in the early steps of retroviral replication appears largely that of a facilitator for reverse transcription and integration. Using a wide variety of cell-free assay systems, the properties of mature NC proteins (e.g. HIV-1 p7(NC) or MLV p10(NC)) as nucleic acid chaperones have been extensively investigated. The effect of NC on tRNA annealing, reverse transcription initiation, minus-strand-transfer, processivity of reverse transcription, plus-strand-transfer, strand-displacement synthesis, 3' processing of viral DNA by integrase, and integrase-mediated strand-transfer has been determined by a large number of laboratories. Interestingly, these reactions can all be accomplished to varying degrees in the absence of NC; some are facilitated by both viral and non-viral proteins and peptides that may or may not be involved in vivo. What is one to conclude from the observation that NC is not strictly required for these necessary reactions to occur? NC likely enhances the efficiency of each of these steps, thereby vastly improving the productivity of infection. In other words, one of the major roles of NC is to enhance the effectiveness of early infection, thereby increasing the probability of productive replication and ultimately of retrovirus survival.

Strand transfer events during HIV-1 reverse transcription

Human immunodeficiency virus type 1 (HIV-1) and other retroviruses replicate through reverse transcription, a process in which the single stranded RNA of the viral genome is converted to a double stranded DNA. The virally encoded reverse transcriptase (RT) mediates reverse transcription through DNA polymerase and RNase H activities. Conversion of the plus strand RNA to plus/minus strand RNA/DNA hybrid involves a transfer of the growing DNA strand from one site on the genomic RNA to another. This is called minus strong-stop DNA transfer. Later synthesis of the second or plus DNA strand involves a second strand transfer, involving a similar mechanism as the minus strand transfer. A basic feature of the strand transfer mechanism is the use of the RT RNase H to remove segments of the RNA template strand from the growing DNA strand, freeing a single stranded region to anneal to the second site. Viral nucleocapsid protein (NC) functions to promote transfer by facilitating this strand exchange process. Two copies of the RNA genomes, sometimes non-identical, are co-packaged in the genomes of retroviruses. The properties of the reverse transcriptase allow a transfer of the growing DNA strand between these genomes to occur occasionally at any point during reverse transcription, producing recombinant viral progeny. Recombination promotes structural diversity of the virus that helps it to survive host immunity and drug therapy. Recombination strand transfer can be forced by a break in the template, or can occur at sites where folding structure of the template pauses the RT, allowing a concentration of RNase H cleavages that promote transfers. Transfer can be a simple one-step process, or can proceed by a complex multi-step invasion mechanism. In this latter process, the second RNA template interacts with the growing DNA strand well behind the DNA 3'-terminus. The newly formed RNA-DNA hybrid expands by branch migration and eventually catches the elongating DNA primer 3'-terminus to complete the transfer. Transfers are also promoted by interactions between the two RNA templates, which accelerate transfer by a proximity effect. Other details of the role of strand transfers in reverse transcription and the biochemical features of the transfer reaction are discussed.

Proximity and branch migration mechanisms in HIV-1 minus strand strong stop DNA transfer

Human immunodeficiency virus type 1 minus strand transfer was measured using a genomic donor-acceptor template system in vitro. Donor RNA D199, having the minimum region required for minus strong stop DNA synthesis, was previously shown to transfer with 35% efficiency to an acceptor RNA representing the 3' repeat region. Donor D520, having an additional 321-nucleotide segment extending into gag, transferred at 75% efficiency. In this study each transfer step was analyzed to account for the difference. Measurement of terminal transfer indicated that the 3' terminus of the cDNA generated using D520 is more accessible for transfer than that of D199. Nevertheless, acceptor competition experiments demonstrated that D520 has a greater preference for invasion-driven versus terminal transfer than D199. Competition mapping showed that the base of the transactivation response element is the primary invasion site for D520, important for efficient acceptor invasion. Acceptors complementary to the invasion and terminal transfer sites, but not the region between, allowed assessment of the significance of hybrid propagation by branch migration. These bipartite acceptors showed that with D520, invasion raises the local concentration of the acceptor for efficient terminal transfer by a proximity effect. However, with D199, invasion is relatively inefficient, and the cDNA 3' terminus is not very accessible. For most transfers that occurred, the acceptor accessed the cDNA 3' end by branch migration. Results suggest that both proximity and branch migration mechanisms contribute to transfers, with the proportion determined by donor-cDNA structure. D520 transfers better because it has greater accessibility for both invasion and terminus transfer.

The single-finger nucleocapsid protein of moloney murine leukemia virus binds and destabilizes the TAR sequences of HIV-1 but does not promote efficiently their annealing

The retroviral nucleocapsid proteins (NCs) are small proteins with either one or two conserved zinc fingers flanked by basic domains. NCs play key roles during reverse transcription by chaperoning the obligatory strand transfers. In HIV-1, the first DNA strand transfer relies on the NCp7-promoted destabilization and subsequent annealing of the transactivation response element, TAR with its complementary cTAR sequence. NCp7 chaperone activity relies mainly on its two folded fingers. Since NCs with a unique zinc finger are encoded by gammaretroviruses such as the canonical Moloney murine leukemia virus (MoMuLV), our objective was to characterize, by fluorescence techniques, the binding and chaperone activities of the NCp10 protein of MoMuLV to the TAR sequences of HIV-1. The unique finger and the flanking 12-25 and 40-48 domains of NCp10 were found to bind and destabilize cTAR stem-loop almost as efficiently as the homologous NCp7 protein. The flanking domains were essential for properly positioning the finger and, notably, the Trp35 residue onto cTAR. Thus, the binding and destabilization determinants scattered on the two NCp7 fingers are encoded by the unique finger of NCp10 and its flanking domains. NCp10 also activates the cTAR/TAR annealing reaction, but less efficiently than NCp7, suggesting that the two NCp7 fingers promote in concert the rate-limiting nucleation of the duplex. Due to its ability to mimic NCp7, the simple structure of NCp10 might be useful to design peptidomimetics aimed at inhibiting HIV replication.

Investigating the mechanism of the nucleocapsid protein chaperoning of the second strand transfer during HIV-1 DNA synthesis

Conversion of the human immunodeficiency virus type 1 (HIV-1) genomic RNA into the proviral DNA by reverse transcriptase involves two obligatory strand transfers that are chaperoned by the nucleocapsid protein (NC). The second strand transfer relies on the annealing of the (-) and (+) copies of the primer binding site, (-)PBS and (+) PBS, which fold into complementary stem-loops (SLs) with terminal single-stranded overhangs. To understand how NC chaperones their hybridization, we investigated the annealing kinetics of fluorescently labelled (+)PBS with various (-)PBS derivatives. In the absence of NC, the (+)/(-)PBS annealing was governed by a second-order pathway nucleated mainly by the single-stranded overhangs of the two PBS SLs. The annealing reaction appeared to be rate-limited by the melting of the stable G.C-rich stem subsequent to the formation of the partially annealed intermediate. A second pathway nucleated through the loops could be detected, but was very minor. NC(11-55), which consists primarily of the zinc finger domain, increased the (-)/(+) PBS annealing kinetics by about sixfold, by strongly activating the interaction between the PBS loops. NC(11-55) also activated (-)/(+) PBS annealing through the single-strand overhangs, but by a factor of only 2. Full-length NC(1-55) further increased the (-)/(+)PBS annealing kinetics by tenfold. The NC-promoted (-)/(+)PBS mechanism proved to be similar with extended (-)DNA molecules, suggesting that it is relevant in the context of proviral DNA synthesis. These findings favour the notion that the ubiquitous role of NC in the viral life-cycle probably relies on the ability of NC to chaperone nucleic acid hybridization via different mechanisms.

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

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.

Effects of nucleic acid local structure and magnesium ions on minus-strand transfer mediated by the nucleic acid chaperone activity of HIV-1 nucleocapsid protein

HIV-1 nucleocapsid protein (NC) is a nucleic acid chaperone, which is required for highly specific and efficient reverse transcription. Here, we demonstrate that local structure of acceptor RNA at a potential nucleation site, rather than overall thermodynamic stability, is a critical determinant for the minus-strand transfer step (annealing of acceptor RNA to (−) strong-stop DNA followed by reverse transcriptase (RT)-catalyzed DNA extension). In our system, destabilization of a stem-loop structure at the 5′ end of the transactivation response element (TAR) in a 70-nt RNA acceptor (RNA 70) appears to be the major nucleation pathway. Using a mutational approach, we show that when the acceptor has a weak local structure, NC has little or no effect. In this case, the efficiencies of both annealing and strand transfer reactions are similar. However, when NC is required to destabilize local structure in acceptor RNA, the efficiency of annealing is significantly higher than that of strand transfer. Consistent with this result, we find that Mg²⁺ (required for RT activity) inhibits NC-catalyzed annealing. This suggests that Mg²⁺ competes with NC for binding to the nucleic acid substrates. Collectively, our findings provide new insights into the mechanism of NC-dependent and -independent minus-strand transfer.

Rapid kinetics of protein-nucleic acid interaction is a major component of HIV-1 nucleocapsid protein's nucleic acid chaperone function

The nucleic acid chaperone activity of the human immunodeficiency virus type-1 (HIV-1) nucleocapsid protein (NC) plays an important role in the retroviral life cycle, in part, by facilitating numerous nucleic acid rearrangements throughout the reverse transcription process. Recent studies have identified duplex destabilization and nucleic acid aggregation as the two major components of NC's chaperone activity. In order to better understand the contribution of the functional domains of NC to these two activities, we used optical tweezers to stretch single lambda DNA molecules through the helix-coil transition in the presence of wild-type or mutant HIV-1 NC. Protein-induced duplex destabilization was measured directly as an average decrease of the force-induced melting free energy, while NC's ability to facilitate strand annealing was determined by the amount of hysteresis in the DNA stretch-relax cycle. By studying zinc-free variants of full-length and truncated NC, the relative contributions of NC's zinc fingers and N-terminal basic domain to the two major components of chaperone activity were elucidated. In addition, examination of NC variants containing mutations affecting one or both zinc finger motifs showed that effective strand annealing activity is correlated with NC's ability to rapidly bind and dissociate from nucleic acids. NC variants with slow on/off rates are inefficient in strand annealing, even though they may still be capable of high affinity nucleic acid binding, duplex destabilization, and/or nucleic acid aggregation. Taken together, these observations establish the rapid kinetics of protein-nucleic acid interaction as another major component of NC's chaperone function.

Stimulation of HIV-1 minus strand strong stop DNA transfer by genomic sequences 3' of the primer binding site

The mechanism of human immunodeficiency virus 1 (HIV-1) minus strand transfer was examined using a genomic RNA sequence-based donor-acceptor template system. The donor RNA, D199, was a 199-nucleotide sequence from the 5'-end of the genome to the primer binding site (PBS) and shared 97 nucleotides of homology with the acceptor RNA. To investigate the influence of RNA structure on transfer, a second donor RNA, D520, was generated by extending the 3'-end of D199 to include an additional 321 nucleotides of the genome. The position of priming, length of homology with the acceptor, and length of cDNA synthesized were identical with the two donors. Interestingly, at 200% NC coating, donor D520 yielded a transfer efficiency of about 75% compared with about 35% with D199. A large proportion of the D520 promoted transfers occurred after the donor RNA was copied to the end. Analysis of donor RNA cleavage, the acceptor invasion site and R homology requirements indicated that transfers with D520 involved a similar but more efficient acceptor invasion mechanism compared with D199. RNA structure probing by RNase T1 and the RT pause profile during synthesis indicated conformational differences between D199 and D520 in the starting structure, and in dynamic structures formed during synthesis within the R region. Overall observations suggest that regions 3' of the primer binding site influence the conformation of the R region of D520 to facilitate steps that promote strand transfer.

Nucleic acid binding and chaperone properties of HIV-1 Gag and nucleocapsid proteins

The Gag polyprotein of HIV-1 is essential for retroviral replication and packaging. The nucleocapsid (NC) protein is the primary region for the interaction of Gag with nucleic acids. In this study, we examine the interactions of Gag and its NC cleavage products (NCp15, NCp9 and NCp7) with nucleic acids using solution and single molecule experiments. The NC cleavage products bound DNA with comparable affinity and strongly destabilized the DNA duplex. In contrast, the binding constant of Gag to DNA was found to be approximately 10-fold higher than that of the NC proteins, and its destabilizing effect on dsDNA was negligible. These findings are consistent with the primary function of Gag as a nucleic acid binding and packaging protein and the primary function of the NC proteins as nucleic acid chaperones. Also, our results suggest that NCp7's capability for fast sequence-nonspecific nucleic acid duplex destabilization, as well as its ability to facilitate nucleic acid strand annealing by inducing electrostatic attraction between strands, likely optimize the fully processed NC protein to facilitate complex nucleic acid secondary structure rearrangements. In contrast, Gag's stronger DNA binding and aggregation capabilities likely make it an effective chaperone for processes that do not require significant duplex destabilization.

During the early phase of HIV-1 DNA synthesis, nucleocapsid protein directs hybridization of the TAR complementary sequences via the ends of their double-stranded stem

Reverse transcription of HIV-1 genomic RNA requires two obligatory strand transfers. During the first strand transfer reaction, the minus strand strong-stop DNA (ss-cDNA) is transferred by hybridization of complementary sequences located at the 3' ends of the ss-cDNA and genomic template, respectively. In HIV-1, the major components of ss-cDNA transfer are the terminally redundant structured TAR elements and the nucleocapsid protein NCp7, which actively chaperones the hybridization of cTAR DNA to TAR. In the present study, we investigated the annealing kinetics of TAR with fluorescently labelled cTAR derivatives both in the absence and in the presence of NC(12-55), a peptide that contains the finger and C-terminal domains of NCp7. The annealing of TAR with cTAR involves two second-order kinetic components that are activated by at least two orders of magnitude by NC(12-55). The NC-promoted activation of cTAR-TAR annealing was correlated with its ability to destabilize the lower half of TAR stem, in order to generate the single-stranded complementary regions for nucleating the duplex structures. The two kinetics components have been assigned to two different pathways. The rapid one does not lead to extended duplex formation but is associated with a limited annealing of the terminal bases of cTAR to TAR. On the other hand, extended duplex formation follows a slower pathway that is limited kinetically by the nucleation of residues located mainly within the central double-stranded segment of both cTAR and TAR stems. An alternative mechanism involving an interaction through TAR and cTAR loops has been observed but is a minor pathway in the present conditions.

Investigation by fluorescence correlation spectroscopy of the chaperoning interactions of HIV-1 nucleocapsid protein with the viral DNA initiation sequences

HIV-1 nucleocapsid protein (NC) exhibits nucleic acid chaperone properties that are important during reverse transcription. Herein, we review and extend our recent investigation by fluorescence correlation spectroscopy (FCS) of the NC chaperone activity on the primer binding site sequences (PBS) of the (-) and (+) DNA strands, which are involved in the second strand transfer during reverse transcription. In the absence of NC, the PBS stem-loops exhibited a fraying limited to the terminal G-C base pair. The kinetics of fraying were significantly activated by NC, a feature that may favour (-)PBS/(+)PBS annealing during the second strand transfer. In addition, NC was found to promote the formation of PBS kissing homodimers through interaction between the loops. These kissing complexes may favour secondary contacts between viral sequences and thus, promote recombination and viral diversity.

Evidence that HIV-1 reverse transcriptase employs the DNA 3' end-directed primary/secondary RNase H cleavage mechanism during synthesis and strand transfer

We previously analyzed strand transfers catalyzed by human immunodeficiency virus, type 1 reverse transcriptase (RT) in a hairpin-containing RNA template system. In this system, RT produces a series of adjacent RNase H cuts before the hairpin base on the first, or donor template that clears a region of the donor, facilitating invasion by the second, or acceptor RNA. Here we analyze characteristics of the prominent cuts before the hairpin base and their role in strand transfers. Analysis of the template cleavage pattern during synthesis suggested that the RT performs DNA 3' end-directed primary and secondary cuts while paused at the hairpin base and that these cuts contribute to creation of the invasion site. RT catalyzed similar cleavages on a substrate representing a paused cDNA-template intermediate. DNA 3' end-directed secondary cuts, which require positioning of the polymerase active site downstream of the primer terminus, had previously not been specifically identified during synthesis. Our findings indicate that during synthesis DNA 3' end-directed primary and secondary cuts occur at pause sites. RT mutants with substitutions at the His(539) residue in the RNase H active site were defective in secondary cleavages. Analysis of the template cleavage pattern generated by the His(539) mutants during synthesis revealed inefficient cleavage at the invasion site, correlating with defects in strand transfer. Overall, results indicate RT can catalyze pause-associated DNA 3' end-directed primary and secondary cuts during synthesis and these cuts can contribute to strand transfer by creation of an invasion site.

Single-molecule FRET studies of important intermediates in the nucleocapsid-protein-chaperoned minus-strand transfer step in HIV-1 reverse transcription

The minus-strand transfer step of HIV-1 reverse transcription is chaperoned by the nucleocapsid protein (NC), which has been shown to facilitate the annealing between the transactivation response element (TAR) RNA and complementary TAR DNA stem-loop structures. In this work, potential intermediates in the mechanism of NC-chaperoned TAR DNA/TAR RNA annealing have been examined using single-molecule fluorescence resonance energy transfer. The interaction between TAR DNA and various DNA oligonucleotides designed to mimic the initial annealing step was monitored to capture potential intermediates along the reaction pathway. Two possible mechanisms of annealing were examined, namely nucleation through the 3'/5' termini, termed the "zipper" complex, or nucleation through the hairpin loops in a "kissing" complex. Intermediates associated with both mechanisms were observed in the presence of NC, and the kinetics of formation of these intermediates were also measured. Thus, the single-molecule experiments support the notion that NC-assisted annealing of TAR DNA:TAR RNA may occur through multiple pathways.

Specific Interactions Between HIV-1 Nucleocapsid Protein and the TAR Element

During retroviral reverse transcription, the minus-strand strong-stop DNA (ss-cDNA) is transferred to the 3' end of the genomic RNA and this requires the repeat (R) sequences present at both ends of the genome. In vitro, the human immunodeficiency virus type 1 (HIV-1) R sequence can promote DNA strand transfer when present in ectopic internal positions. Using HIV-1 model systems, the R sequences and nucleocapsid protein (NC) were found to be key determinants of ss-cDNA transfer. To gain insights into specific interactions between HIV-1 NC and RNA and the influence of NC on R folding, we investigated the secondary structures of R in two natural contexts, namely at the 5' or 3' end of RNAs representing the terminal regions of the genome, and in two ectopic internal positions that also support efficient minus-strand transfer. To investigate the roles of NC zinc fingers and flanking basic domains in the NC/RNA interactions, we used NC mutants. Analyses of the viral RNA/NC complexes by chemical and enzymatic probings, and gel retardation assays were performed under conditions allowing ss-cDNA transfer by reverse transcriptase. We report that NC binds the TAR apical loop specifically in the four genetic contexts without changing the folding of the TAR hairpin and R region significantly, and this requires the NC zinc fingers. In addition, we show that efficient annealing of cTAR DNA to the 3' R relies on sequence complementarities between TAR and cTAR terminal loops. These findings suggest that the TAR apical loop in the acceptor RNA is the initiation site for the annealing reaction that is chaperoned by NC during the minus-strand transfer.

Structural determinants of HIV-1 nucleocapsid protein for cTAR DNA binding and destabilization, and correlation with inhibition of self-primed DNA synthesis

The nucleocapsid protein (NC) of human immunodeficiency virus type 1 (HIV-1) is formed of two highly conserved CCHC zinc fingers flanked by small basic domains. NC is required for the two obligatory strand transfers in viral DNA synthesis through its nucleic acid chaperoning properties. The first DNA strand transfer relies on NC's ability to bind and destabilize the secondary structure of complementary transactivation response region (cTAR) DNA, to inhibit self-priming, and to promote the annealing of cTAR to TAR RNA. To further investigate NC chaperone properties, our aim was to identify by fluorescence spectroscopy and gel electrophoresis, the NC structural determinants for cTAR binding and destabilization, and for the inhibition of self-primed DNA synthesis on a model system using a series of NC mutants and HIV-1 reverse transcriptase. NC destabilization and self-priming inhibition properties were found to be supported by the two fingers in their proper context and the basic (29)RAPRKKG(35) linker. The strict requirement of the native proximal finger suggests that its hydrophobic platform (Val13, Phe16, Thr24 and Ala25) is crucial for binding, destabilization and inhibition of self-priming. In contrast, only partial folding of the distal finger is required, probably for presenting the Trp37 residue in an appropriate orientation. Also, Trp37 and the hydrophobic residues of the proximal finger appear to be essential for the propagation of the melting from the cTAR ends up to the middle of the stem. Finally, both N-terminal and C-terminal basic domains contribute to cTAR binding but not to its destabilization.

Secondary structure and secondary structure dynamics of DNA hairpins complexed with HIV-1 NC protein

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.

Acceptor RNA cleavage profile supports an invasion mechanism for HIV-1 minus strand transfer

We previously proposed that HIV-1 minus strand transfer occurs by an acceptor invasion-initiated multi-step mechanism. During synthesis of minus strong stop DNA, reverse transcriptase (RT) transiently pauses at the base of TAR before continuing synthesis. Pausing promotes RT-RNase H cleavage of the donor RNA, exposing regions of the cDNA. The acceptor RNA then invades at these locations to interact with the minus strong stop DNA. Whereas primer extension continues on the donor RNA, the cDNA-acceptor hybrid expands by branch migration until transfer of the primer terminus is completed. We present results here showing that the interaction of the acceptor RNA and the cDNA can be determined by examining the time-dependent cleavage of the acceptor RNA by RNase H. Our approach utilizes a combination of RT-RNase H and Escherichia coli RNase H to allow assessment of acceptor-cDNA interactions at high sensitivity. Results show an initial interaction of the acceptor RNA with cDNA at the base of TAR. We observe a time-dependent shift in RNase H susceptibility along the length of the acceptor toward the 5' end, suggesting hybrid propagation from the initial invasion point. Control experiments validate that the RNase H cleavage profile represents the formation and expansion of the acceptor-DNA interaction and that the process is promoted by the nucleocapsid. Observations with this new approach lend additional support to the proposed multistep transfer mechanism.

HIV-1 nucleocapsid protein binds to the viral DNA initiation sequences and chaperones their kissing interactions

The chaperone properties of the human immunodeficiency virus type 1 (HIV-1) nucleocapsid protein (NC) are required for the two obligatory strand transfer reactions occurring during viral DNA synthesis. The second strand transfer relies on the destabilization and the subsequent annealing of the primer binding site sequences (PBS) at the 3' end of the (-) and (+) DNA strands. To characterize the binding and chaperone properties of NC on the (-)PBS and (+)PBS sequences, we monitored by steady-state and time-resolved fluorescence spectroscopy as well as by fluorescence correlation spectroscopy the interaction of NC with wild type and mutant oligonucleotides corresponding to the (-)PBS and (+)PBS hairpins. NC was found to bind with high affinity to the loop, the stem and the single-stranded protruding sequence of both PBS sequences. NC induces only a limited destabilization of the secondary structure of both sequences, activating the transient melting of the stem only during its "breathing" period. This probably results from the high stability of the PBS due to the four G-C pairs in the stem. In contrast, NC directs the formation of "kissing" homodimers efficiently for both (-)PBS and (+)PBS sequences. Salt-induced dimerization and mutations in the (-)PBS sequence suggest that these homodimers may be stabilized by two intermolecular G-C Watson-Crick base-pairs between the partly self-complementary loops. The propensity of NC to promote the dimerization of partly complementary sequences may favor secondary contacts between viral sequences and thus, recombination and viral diversity.

Alteration of nucleic acid structure and stability modulates the efficiency of minus-strand transfer mediated by the HIV-1 nucleocapsid protein

During human immunodeficiency virus type 1 minus-strand transfer, the nucleocapsid protein (NC) facilitates annealing of the complementary repeat regions at the 3'-ends of acceptor RNA and minus-strand strong-stop DNA ((-) SSDNA). In addition, NC destabilizes the highly structured complementary trans-activation response element (TAR) stem-loop (TAR DNA) at the 3'-end of (-) SSDNA and inhibits TAR-induced self-priming, a dead-end reaction that competes with minus-strand transfer. To investigate the relationship between nucleic acid secondary structure and NC function, a series of truncated (-) SSDNA and acceptor RNA constructs were used to assay minus-strand transfer and self-priming in vitro. The results were correlated with extensive enzymatic probing and mFold analysis. As the length of (-) SSDNA was decreased, self-priming increased and was highest when the DNA contained little more than TAR DNA, even if NC and acceptor were both present; in contrast, truncations within TAR DNA led to a striking reduction or elimination of self-priming. However, destabilization of TAR DNA was not sufficient for successful strand transfer: the stability of acceptor RNA was also crucial, and little or no strand transfer occurred if the RNA was highly stable. Significantly, NC may not be required for in vitro strand transfer if (-) SSDNA and acceptor RNA are small, relatively unstructured molecules with low thermodynamic stabilities. Collectively, these findings demonstrate that for efficient NC-mediated minus-strand transfer, a delicate thermodynamic balance between the RNA and DNA reactants must be maintained.

Role of the structure of the top half of HIV-1 cTAR DNA on the nucleic acid destabilizing activity of the nucleocapsid protein NCp7

The viral nucleic acid chaperone protein NCp7 of HIV-1 assists the two obligatory strand transfers required for the conversion of the genomic RNA into double-stranded DNA by reverse transcriptase. The first strand transfer necessitates the annealing of the early product of cDNA synthesis, the minus strand strong stop DNA (ss-cDNA) to the 3' end of the genomic RNA. The hybridization reaction involves regions containing imperfect stem-loop (SL) structures, namely the TAR RNA at the 3' end of the genomic RNA and the complementary sequence cTAR at the 3' end of ss-cDNA. To pursue the characterization of the interaction between NCp7 and cTAR DNA, we investigated by absorbance, steady-state and time-resolved fluorescence spectroscopy, the interaction of NCp7 with wild-type and mutated DNAs representing the top half of cTAR. NCp7 was found to activate the transient melting of this cTAR DNA structure but less efficiently than that of cTAR lower half. The NCp7-induced destabilization of cTAR top half is dependent upon the three nucleotides bulging out of the stem, which thus represent a melting initiation site. In contrast, despite its ability to bind NCp7, the top loop does not play any significant role in NCp7-mediated melting. Thermodynamic data further suggest that NCp7-mediated destabilization of this cTAR structure correlates with the free energy changes afforded by destabilizing motifs like loops and bulges within the SL secondary structure. Interestingly, since NCp7 melts only short double-stranded sequences, destabilizing motifs need to be regularly positioned along the genomic sequence in order to promote strand transfer and thus genetic recombination during proviral DNA synthesis.

Steps of the acceptor invasion mechanism for HIV-1 minus strand strong stop transfer

Minus strand strong stop transfer is obligatory for completion of HIV-1 minus strand synthesis. We previously showed evidence for an acceptor invasion-initiated mechanism for minus strand transfer. In the present study, we examined the major acceptor invasion initiation site using a minus strand transfer system in vitro, containing the 97-nucleotide full-length R region. A series of DNA oligonucleotides complementary to different regions of the cDNA was designed to interfere with transfer. Oligomers covering the region around the base of the TAR hairpin were most effective in inhibiting transfer, suggesting that the hairpin base is a preferred site for acceptor invasion. The strong pausing of reverse transcriptase at the base of the TAR and the concomitant RNase H cleavages 10-19 nucleotides behind the pause site correlated with the location of the invasion site. Oligomers closer to the 5'-end of R also inhibited transfer, though less effectively, presumably by blocking strand exchange and branch migration. We propose that pausing of reverse transcriptase at the base of TAR increases RNase H cleavages, creating gaps for acceptor invasion and transfer initiation. Strand exchange then propagates by branch migration, displacing the fragmented donor RNA, including the fragment at the 5' terminus. The primer terminus switches to the acceptor, completing the transfer. Nucleocapsid (NC) protein stimulated transfer efficiency by 5-7-fold. NC enhanced RNase H cleavages close to the TAR base, creating more effective invasion sites for efficient transfer. Most likely, NC also stimulates transfer by promoting strand exchange invasion and branch migration.

Zinc finger-dependent HIV-1 nucleocapsid protein-TAR RNA interactions

In the minus-strand transfer step of HIV-1 reverse transcription, the nucleocapsid protein (NC) promotes annealing of the 3' 'R' (repeat) region of the RNA genome to its complementary sequence located in the newly synthesized minus-strand strong-stop DNA. The R region contains the highly stable transactivation response (TAR) RNA hairpin. To gain insights into the molecular details of TAR RNA-NC interactions, we carried out hydroxyl radical footprinting, as well as gel-shift and fluorescence anisotropy binding assays using wild-type and mutant forms of NC. Our results support the conclusion that NC variants with mutations in their zinc finger domains have dramatically altered TAR RNA binding interactions relative to wild-type NC. These data demonstrate that a specific zinc finger architecture is required for optimal TAR RNA binding, and help to explain the requirement for the zinc finger motifs of NC in its role as a nucleic acid chaperone in minus-strand transfer.

Secondary structure in the nucleic acid affects the rate of HIV-1 nucleocapsid-mediated strand annealing

We studied the effects of human immunodeficiency virus type 1 (HIV-1) nucleocapsid (NC) protein on the kinetics of annealing of nucleic acids using model substrates derived from the 3' end of the HIV-1 minus-strand strong-stop DNA (-sssDNA). We used HIV-1 reverse transcriptase (RT) to monitor the annealing reaction. Using several different DNA primers and acceptor oligonucleotides, we found that the rate of annealing increased with the size of the complementary region of the primer and the acceptor strands and decreased when secondary structures could be formed in either the primer or the acceptor strands. The secondary structure had a larger effect on the rate of annealing if the secondary structure extends to the 3' end of the nucleic acid(s). NC protein reduced the rate of annealing between strands with short homologies. NC had no major effect on the rate of annealing when there were at least 13 bases of complementarity between the primer and the acceptor strands and neither strand could form a stable secondary structure. NC increased the rate of annealing when the primer and/or the acceptor strand could form a secondary structure in the region of complementarity. When two strands were in competition as acceptors in an annealing reaction, the specificity of the annealing was determined by the length of the complementarity between the primer and the acceptor strands, the presence or the absence of secondary structures in the primer and/or the acceptor strand, and the presence or the absence of NC in the reaction. This suggests that NC facilitates strand transfer where the nucleic acids have considerable secondary structure (for example, the first strand transfers for viruses whose genomes have considerable secondary structure at their 3' ends). However, NC also appears to increase the fidelity of recombination by reducing strand transfers between segments that have limited complementarity.

Human immunodeficiency virus type 2 reverse transcriptase activity in model systems that mimic steps in reverse transcription

Human immunodeficiency virus type 2 (HIV-2) infection is a serious problem in West Africa and Asia. However, there have been relatively few studies of HIV-2 reverse transcriptase (RT), a potential target for antiviral therapy. Detailed knowledge of HIV-2 RT activities is critical for development of specific high-throughput screening assays of potential inhibitors. Here, we have conducted a systematic evaluation of HIV-2 RT function, using assays that model specific steps in reverse transcription. Parallel studies were performed with HIV-1 RT. In general, under standard assay conditions, the polymerase and RNase H activities of the two enzymes were comparable. However, when the RT concentration was significantly reduced, HIV-2 RT was less active than the HIV-1 enzyme. HIV-2 RT was also impaired in its ability to catalyze secondary RNase H cleavage in assays that mimic tRNA primer removal during plus-strand transfer and degradation of genomic RNA fragments during minus-strand DNA synthesis. In addition, initiation of plus-strand DNA synthesis was much less efficient with HIV-2 RT than with HIV-1 RT. This may reflect architectural differences in the primer grip regions in the p66 (HIV-1) and p68 (HIV-2) palm subdomains of the two enzymes. The implications of our findings for antiviral therapy are discussed.

Evidence for the differential effects of nucleocapsid protein on strand transfer in various regions of the HIV genome

An in vitro strand transfer assay that mimicked recombinational events occurring during reverse transcription in HIV-1 was used to assess the role of nucleocapsid protein (NC) in strand transfer. Strand transfer in highly structured nucleic acid species from the U3 3' long terminal repeats, gag-pol frameshift region, and Rev response element were strongly enhanced by NC. In contrast, weakly structured templates from the env and pol-vif regions transferred well without NC and showed lower enhancement. The lack of strong polymerase pause sites in the latter regions demonstrated that non-pause driven mechanisms could also promote transfer. Assays conducted using NC zinc finger mutants supported a differential role for the two fingers in strand transfer with finger 1 (N-terminal) being more important on highly structured RNAs. Overall this report suggests a role for structural intricacies of RNA templates in determining the extent of influence of NC on recombination and illustrates that strand transfer may occur by several different mechanisms depending on the structural nature of the RNA.

Impact of the terminal bulges of HIV-1 cTAR DNA on its stability and the destabilizing activity of the nucleocapsid protein NCp7

Reverse transcription of HIV-1 genomic RNA to double-stranded DNA by reverse transcriptase (RT) is a critical step in HIV-1 replication. This process relies on two viral proteins, the RT enzyme and nucleocapsid protein NCp7 that has well documented nucleic acid chaperone properties. At the beginning of the linear DNA synthesis, the newly made minus-strand strong-stop DNA ((-)ssDNA) is transferred to the 3'end of the genomic RNA by means of an hybridization reaction between transactivation response element (TAR) RNA and cTAR DNA sequences. Since both TAR sequences exhibit stable hairpin structures, NCp7 needs to destabilize the TAR structures in order to chaperone their hybridization. To further characterize the relationships between TAR stability and NC-mediated destabilization, the role of the A(49) and G(52) bulged residues in cTAR DNA stability was investigated. The stability of cTAR and mutants where one or the two terminal bulges were replaced by base-pairs as well as the NCp7-mediated destabilization of these cTAR sequences were examined. Thermodynamic data indicate that the two bulges cooperatively destabilize cTAR by reducing the stacking interactions between the bases. This causes a free energy change of about 6.4 kcal/mol and seems to be critical for NC activity. Time-resolved fluorescence data of doubly labelled cTAR derivatives suggest that NC-mediated melting of cTAR ends propagates up to the 10C.A(44) mismatch or T(40) bulge. Fluorescence correlation spectroscopy using two-photon excitation was also used to monitor cTAR ends fraying by NC. Results show that NC causes a very significant increase of cTAR ends fraying, probably limited to the terminal base-pair in the case of cTAR mutants. Since the TAR RNA and cTAR DNA bulges or mismatches appear well conserved among all HIV-1 strains, the present data support the notion of a co-evolutionary relationship between TAR and NC activity.

Mechanism of minus strand strong stop transfer in HIV-1 reverse transcription

Retrovirus minus strand strong stop transfer (minus strand transfer) requires reverse transcriptase-associated RNase H, R sequence homology, and viral nucleocapsid protein. The minus strand transfer mechanism in human immunodeficiency virus-1 was examined in vitro with purified protein and substrates. Blocking donor RNA 5'-end cleavage inhibited transfers when template homology was 19 nucleotides (nt) or less. Cleavage of the donor 5'-end occurred prior to formation of transfer products. This suggests that when template homology is short, transfer occurs through a primer terminus switch-initiated mechanism, which requires cleavage of the donor 5' terminus. On templates with 26-nt and longer homology, transfer occurred before cleavage of the donor 5' terminus. Transfer was unaffected when donor 5'-end cleavages were blocked but was reduced when internal cleavages within the donor were restricted. Based on the overall data, we conclude that in human immunodeficiency virus-1, which contains a 97-nt R sequence, minus strand transfer occurs through an acceptor invasion-initiated mechanism. Transfer is initiated at internal regions of the homologous R sequence without requiring cleavage at the donor 5'-end. The acceptor invades at gaps created by reverse transcriptase-RNase H in the donor-cDNA hybrid. The fragmented donor is eventually strand-displaced by the acceptor, completing the transfer.

Suppression of an intrinsic strand transfer activity of HIV-1 Tat protein by its second-exon sequences

The Tat protein of human immunodeficiency virus type 1 (HIV-1) has been shown to restrict premature reverse transcription at late stages of virus infection and to thus ensure the integrity of the viral RNA genome for packaging. To gain further insights into the roles of Tat in HIV-1 reverse transcription, we have assessed its effects on the first-strand transfer during the synthesis of minus-strand DNA through use of a reconstituted cell-free system. The results demonstrated that a form of Tat, containing only the first exon (Tat72), was able to enhance the first-strand transfer as efficiently as did the viral nucleocapsid protein. Coincidentally, this form of Tat was unable to inhibit the production of minus-strand strong-stop DNA. Further studies with various mutated forms of Tat showed that its Cys-rich region, rather than the core and Arg-rich domains, was essential for this strand transfer activity. Moreover, this activity of Tat is largely independent of the TAR RNA structure. Although full-length Tat protein (Tat86) was also able to promote strand transfer, this activity was limited by a strong overall inhibition of reverse transcription because of the presence of the second Tat exon. Other nucleic-acid-binding proteins (e.g., single-strand DNA-binding protein) were employed as negative controls and were unable to promote strand transfer in these assays. We propose that Tat possesses nucleic acid chaperone activity and can promote the first-strand transfer during HIV-1 reverse transcription; however, these activities are restricted by the second Tat exon, and the roles of these Tat activities in viral replication remain to be elucidated.

Destabilization of the HIV-1 complementary sequence of TAR by the nucleocapsid protein through activation of conformational fluctuations

The nucleocapsid protein NCp7 of HIV-1 possesses nucleic acid chaperone properties that are critical for the two obligatory strand transfer reactions required for the synthesis of a complete proviral DNA by reverse transcriptase. The first DNA strand transfer relies on the destabilization by NCp7 of double-stranded segments of the transactivation response region (TAR) sequence at the 3' end of the genomic RNA and the complementary sequence cTAR at the 3' terminus of minus strong-stop DNA, the early product of reverse transcription. In order to determine the dynamics of NCp7-mediated nucleic acid destabilization, we investigated by time-resolved fluorescence spectroscopy and two photon fluorescence correlation spectroscopy, the interaction of a doubly labeled cTAR sequence with NC(12-55) containing NCp7 CCHC zinc fingers and flanking basic amino acid residues. From the chemical rates and the activation energy associated with the conformational fluctuations observed in the absence of NC, it is concluded that such fluctuations are associated with the opening and closing of the double-stranded terminal segments of cTAR. The destabilizing activity of NC(12-55) occurs mainly through a major increase of the opening rate constant of cTAR. Moreover, NC appears to augment the number of pathways between the open and closed states of cTAR, suggesting that it initiates melting of base-pairs at different locations within the terminal segments of cTAR. This activity of NC on the dynamics of cTAR secondary structure is thought to be critical for the formation of the cTAR-TAR complex, which is essential for the specificity and extent of proviral DNA synthesis by reverse transcriptase.

Nucleic acid conformational changes essential for HIV-1 nucleocapsid protein-mediated inhibition of self-priming in minus-strand transfer

Reverse transcription of the HIV-1 genome is a complex multi-step process. HIV-1 nucleocapsid protein (NC) is a nucleic acid chaperone protein that has been shown to greatly facilitate the nucleic acid rearrangements that precede the minus-strand transfer step in reverse transcription. NC destabilizes the highly structured transactivation response region (TAR) present in the R region of the RNA genome, as well as a complementary hairpin structure ("TAR DNA") at the 3'-end of the newly synthesized minus-strand strong-stop DNA ((-) SSDNA). Melting of the latter structure inhibits a self-priming (SP) reaction that competes with the strand transfer reaction. In an in vitro minus-strand transfer system consisting of a (-) SSDNA mimic and a TAR-containing acceptor RNA molecule, we find that when both nucleic acids are present, NC facilitates formation of the transfer product and the SP reaction is greatly reduced. In contrast, in the absence of the acceptor RNA, NC has only a small inhibitory effect on the SP reaction. To further investigate NC-mediated inhibition of SP, we developed a FRET-based assay that allows us to directly monitor conformational changes in the TAR DNA structure upon NC binding. Although the majority ( approximately 71%) of the TAR DNA molecules assume a folded hairpin conformation in the absence of NC, two minor "semi-folded" and "unfolded" populations are also observed. Upon NC binding to the TAR DNA alone, we observe a modest shift in the population towards the less-folded states. In the presence of the RNA acceptor molecule, NC binding to TAR DNA results in a shift of the majority of molecules to the unfolded state. These measurements help to explain why acceptor RNA is required for significant inhibition of the SP reaction by NC, and support the hypothesis that NC-mediated annealing of nucleic acids is a concerted process wherein the unwinding step occurs in synchrony with hybridization.