Affinities of the nucleocapsid protein for variants of SL3 RNA in HIV-1

Genome sequence analysis suggests coevolution of the DIS, SD, and Psi hairpins in HIV-1 genomes

HIV-1 RNA dimerization is a critical step in viral life cycle. It is a prerequisite for genome packaging and plays an important role in reverse transcription and recombination. Dimerization is promoted by the DIS (dimerization initiation site) hairpin located in the 5' leader of HIV-1 genome. Despite the high genetic diversity in HIV-1 group M, only five apical loops (AAGCGCGCA, AAGUGCGCA, AAGUGCACA, AGGUGCACA and AGUGCAC) are commonly found in DIS hairpins. We refer to the parent DISes with these apical loops as DIS_Lai, DIS_Trans, DIS_F, DIS_Mal, and DIS_C, respectively. Based on identity or similarity of DIS hairpins to parent DISes, we distributed HIV-1 M genomes into five dimerization groups. Comparison of the primary and secondary structures of DIS, SD and Psi hairpins in about 3000 HIV-1 M genomes showed that the mutation frequencies at particular nucleotide positions of these hairpins differ among the dimerization groups, and DIS_F may be an origin of other parent DISes. We found that DIS, SD and Psi hairpins have hundreds of variants, only some of them occurring rather frequently. The lower part of DIS hairpin with G x AGG internal loop is highly conserved in both HIV-1 and SIV genomes. We supposed that the G-quadruplex, located 56 nts downstream of the Gag start codon, may participate in switching of HIV-1 leader RNA from BMH (branched multiple hairpins) to LDI (long distance interaction) conformation.

Insights into the secondary and tertiary structure of the Bovine Viral Diarrhea Virus Internal Ribosome Entry Site

The internal ribosome entry site (IRES) RNA of bovine viral diarrhoea virus (BVDV), an economically significant Pestivirus, is required for the cap-independent translation of viral genomic RNA. Thus, it is essential for viral replication and pathogenesis. We applied a combination of high-throughput biochemical RNA structure probing (SHAPE-MaP) and in silico modelling approaches to gain insight into the secondary and tertiary structures of BVDV IRES RNA. Our study demonstrated that BVDV IRES RNA in solution forms a modular architecture composed of three distinct structural domains (I-III). Two regions within domain III are represented in tertiary interactions to form an H-type pseudoknot. Computational modelling of the pseudoknot motif provided a fine-grained picture of the tertiary structure and local arrangement of helices in the BVDV IRES. Furthermore, comparative genomics and consensus structure predictions revealed that the pseudoknot is evolutionarily conserved among many Pestivirus species. These studies provide detailed insight into the structural arrangement of BVDV IRES RNA H-type pseudoknot and encompassing motifs that likely contribute to the optimal functionality of viral cap-independent translation element.

Overview of the Nucleic-Acid Binding Properties of the HIV-1 Nucleocapsid Protein in Its Different Maturation States

HIV-1 Gag polyprotein orchestrates the assembly of viral particles. Its C-terminus consists of the nucleocapsid (NC) domain that interacts with nucleic acids, and p1 and p6, two unstructured regions, p6 containing the motifs to bind ALIX, the cellular ESCRT factor TSG101 and the viral protein Vpr. The processing of Gag by the viral protease subsequently liberates NCp15 (NC-p1-p6), NCp9 (NC-p1) and NCp7, NCp7 displaying the optimal chaperone activity of nucleic acids. This review focuses on the nucleic acid binding properties of the NC domain in the different maturation states during the HIV-1 viral cycle.

Structural Explorations of NCp7-Nucleic Acid Complexes Give Keys to Decipher the Binding Process

A comprehensive view of all the structural aspects related to NCp7 is essential to understand how this protein, crucial in many steps of the HIV-1 cycle, binds and anneals nucleic acids (NAs), mainly thanks to two zinc fingers, ZF1 and ZF2. Here, we inspected the structural properties of the available experimental models of NCp7 bound to either DNA or RNA molecules, or free of ligand. Our analyses included the characterization of the relative positioning of ZF1 and ZF2, accessibility measurements and the exhaustive, quantitative mapping of the contacts between amino acids and nucleotides by a recent tessellation method, VLDM. This approach unveiled the intimate connection between NA binding process and the conformations explored by the free protein. It also provided new insights into the functional specializations of ZF1 and ZF2. The larger accessibility of ZF2 in free NCp7 and the consistency of the ZF2/NA interface in different models and conditions give ZF2 the lead of the binding process. ZF1 contributes to stabilize the complexes through various organizations of the ZF1/NA interface. This work outcome is a global binding scheme of NCp7 to DNA and RNA, and an example of how protein-NA complexes are stabilized.

Potential inhibition of HIV-1 encapsidation by oligoribonucleotide-dendrimer nanoparticle complexes

Background

Encapsidation, the process during which the genomic RNA of HIV is packaged into viral particles, is an attractive target for antiviral therapy. This study explores a novel nanotechnology-based strategy to inhibit HIV encapsidation by an RNA decoy mechanism. The design of the 16-mer oligoribonucleotide (RNA) decoy is based on the sequence of stem loop 3 (SL3) of the HIV packaging signal (Ψ). Recognition of the packaging signal is essential to the encapsidation process. It is theorized that the decoy RNA, by mimicking the packaging signal, will disrupt HIV packaging if efficiently delivered into lymphocytes by complexation with a carbosilane dendrimer. The aim of the study is to measure the uptake, toxicity, and antiviral activity of the dendrimer–RNA nanocomplex.

Materials and methods

A dendriplex was formed between cationic carbosilane dendrimers and the RNA decoy. Uptake of the fluorescein-labeled RNA into MT4 lymphocytes was determined by flow cytometry and confocal microscopy. The cytoprotective effect (50% effective concentration [EC₅₀]) and the effect on HIV replication were determined in vitro by the methylthiazolyldiphenyl-tetrazolium bromide (MTT) assay and viral load measurements, respectively.

Results

Flow cytometry and confocal imaging demonstrated efficient transfection of lymphocytes. The dendriplex containing the Ψ decoy showed some activity (EC₅₀ =3.20 µM, selectivity index =8.4). However, there was no significant suppression of HIV viral load.

Conclusion

Oligoribonucleotide decoys containing SL3 of the packaging sequence are efficiently delivered into lymphocytes by carbosilane dendrimers where they exhibit a modest cytoprotective effect against HIV infection.

HIV-1 Pr55Gag binds genomic and spliced RNAs with different affinity and stoichiometry

The HIV-1 Pr55^Gag precursor specifically selects genomic RNA (gRNA) from a large variety of cellular and spliced viral RNAs (svRNAs), however the molecular mechanisms of this selective recognition remains poorly understood. To gain better understanding of this process, we analyzed the interactions between Pr55^Gag and a large panel of viral RNA (vRNA) fragments encompassing the main packaging signal (Psi) and its flanking regions by fluorescence spectroscopy. We showed that the gRNA harbors a high affinity binding site which is absent from svRNA species, suggesting that this site might be crucial for selecting the HIV-1 genome. Our stoichiometry analysis of protein/RNA complexes revealed that few copies of Pr55^Gag specifically associate with the 5' region of the gRNA. Besides, we found that gRNA dimerization significantly impacts Pr55^Gag binding, and we confirmed that the internal loop of stem-loop 1 (SL1) in Psi is crucial for specific interaction with Pr55^Gag. Our analysis of gRNA fragments of different length supports the existence of a long-range tertiary interaction involving sequences upstream and downstream of the Psi region. This long-range interaction might promote optimal exposure of SL1 for efficient Pr55^Gag recognition. Altogether, our results shed light on the molecular mechanisms allowing the specific selection of gRNA by Pr55^Gag among a variety of svRNAs, all harboring SL1 in their first common exon.

Studies of RNA Sequence and Structure Using Nanopores

Nanopores are powerful single-molecule sensors with nanometer scale dimensions suitable for detection, quantification, and characterization of nucleic acids and proteins. Beyond sequencing applications, both biological and solid-state nanopores hold great promise as tools for studying the biophysical properties of RNA. In this review, we highlight selected landmark nanopore studies with regards to RNA sequencing, microRNA detection, RNA/ligand interactions, and RNA structural/conformational analysis.

Pulse dipolar ESR of doubly labeled mini TAR DNA and its annealing to mini TAR RNA

Pulse dipolar electron-spin resonance in the form of double electron electron resonance was applied to strategically placed, site-specifically attached pairs of nitroxide spin labels to monitor changes in the mini TAR DNA stem-loop structure brought on by the HIV-1 nucleocapsid protein NCp7. The biophysical structural evidence was at Ångstrom-level resolution under solution conditions not amenable to crystallography or NMR. In the absence of complementary TAR RNA, double labels located in both the upper and the lower stem of mini TAR DNA showed in the presence of NCp7 a broadened distance distribution between the points of attachment, and there was evidence for several conformers. Next, when equimolar amounts of mini TAR DNA and complementary mini TAR RNA were present, NCp7 enhanced the annealing of their stem-loop structures to form duplex DNA-RNA. When duplex TAR DNA-TAR RNA formed, double labels initially located 27.5 Å apart at the 3'- and 5'-termini of the 27-base mini TAR DNA relocated to opposite ends of a 27 bp RNA-DNA duplex with 76.5 Å between labels, a distance which was consistent with the distance between the two labels in a thermally annealed 27-bp TAR DNA-TAR RNA duplex. Different sets of double labels initially located 26-27 Å apart in the mini TAR DNA upper stem, appropriately altered their interlabel distance to ~35 Å when a 27 bp TAR DNA-TAR RNA duplex formed, where the formation was caused either through NCp7-induced annealing or by thermal annealing. In summary, clear structural evidence was obtained for the fraying and destabilization brought on by NCp7 in its biochemical function as an annealing agent and for the detailed structural change from stem-loop to duplex RNA-DNA when complementary RNA was present.

Global redesign of a native β-barrel scaffold

One persistent challenge in membrane protein design is accomplishing extensive modifications of proteins without impairing their functionality. A truncation derivative of the ferric hydroxamate uptake component A (FhuA), which featured the deletion of the 160-residue cork domain and five large extracellular loops, produced the conversion of a non-conductive, monomeric, 22-stranded β-barrel protein into a large-conductance protein pore. Here, we show that this redesigned β-barrel protein tolerates an extensive alteration in the internal surface charge, encompassing 25 negative charge neutralizations. By using single-molecule electrophysiology, we noted that a commonality of various truncation FhuA protein pores was the occurrence of 33% blockades of the unitary current at very high transmembrane potentials. We determined that these current transitions were stimulated by their interaction with an external cationic polypeptide, which occurred in a fashion dependent on the surface charge of the pore interior as well as the polypeptide characteristics. This study shows promise for extensive engineering of a large monomeric β-barrel protein pore in molecular biomedical diagnosis, therapeutics, and biosensor technology.

Single aromatic residue location alters nucleic acid binding and chaperone function of FIV nucleocapsid protein

Feline immunodeficiency virus (FIV) is a retrovirus that infects domestic cats, and is an excellent animal model for human immunodeficiency virus type 1 (HIV-1) pathogenesis. The nucleocapsid (NC) protein is critical for replication in both retroviruses. FIV NC has several structural features that differ from HIV-1 NC. While both NC proteins have a single conserved aromatic residue in each of the two zinc fingers, the aromatic residue on the second finger of FIV NC is located on the opposite C-terminal side relative to its location in HIV-1 NC. In addition, whereas HIV-1 NC has a highly charged cationic N-terminal tail and a relatively short C-terminal extension, the opposite is true for FIV NC. To probe the impact of these differences on the nucleic acid (NA) binding and chaperone properties of FIV NC, we carried out ensemble and single-molecule assays with wild-type (WT) and mutant proteins. The ensemble studies show that FIV NC binding to DNA is strongly electrostatic, with a higher effective charge than that observed for HIV-1 NC. The C-terminal basic domain contributes significantly to the NA binding capability of FIV NC. In addition, the non-electrostatic component of DNA binding is much weaker for FIV NC than for HIV-1 NC. Mutation of both aromatic residues in the zinc fingers to Ala (F12A/W44A) further increases the effective charge of FIV NC and reduces its non-electrostatic binding affinity. Interestingly, switching the location of the C-terminal aromatic residue to mimic the HIV-1 NC sequence (N31W/W44A) reduces the effective charge of FIV NC and increases its non-electrostatic binding affinity to values similar to HIV-1 NC. Consistent with the results of these ensemble studies, single-molecule DNA stretching studies show that while WT FIV NC has reduced stacking capability relative to HIV-1 NC, the aromatic switch mutant recovers the ability to intercalate between the DNA bases. Our results demonstrate that altering the position of a single aromatic residue switches the binding mode of FIV NC from primarily electrostatic binding to more non-electrostatic binding, conferring upon it NA interaction properties comparable to that of HIV-1 NC.

Differential contribution of basic residues to HIV-1 nucleocapsid protein's nucleic acid chaperone function and retroviral replication

The human immunodeficiency virus type 1 (HIV-1) nucleocapsid (NC) protein contains 15 basic residues located throughout its 55-amino acid sequence, as well as one aromatic residue in each of its two CCHC-type zinc finger motifs. NC facilitates nucleic acid (NA) rearrangements via its chaperone activity, but the structural basis for this activity and its consequences in vivo are not completely understood. Here, we investigate the role played by basic residues in the N-terminal domain, the N-terminal zinc finger and the linker region between the two zinc fingers. We use in vitro ensemble and single-molecule DNA stretching experiments to measure the characteristics of wild-type and mutant HIV-1 NC proteins, and correlate these results with cell-based HIV-1 replication assays. All of the cationic residue mutations lead to NA interaction defects, as well as reduced HIV-1 infectivity, and these effects are most pronounced on neutralizing all five N-terminal cationic residues. HIV-1 infectivity in cells is correlated most strongly with NC’s NA annealing capabilities as well as its ability to intercalate the DNA duplex. Although NC’s aromatic residues participate directly in DNA intercalation, our findings suggest that specific basic residues enhance these interactions, resulting in optimal NA chaperone activity.

Sampling a biomarker of the human immunodeficiency virus across a synthetic nanopore

One primary goal in nanobiotechnology is designing new methodologies for molecular biomedical diagnosis at stages much earlier than currently possible and without use of expensive reagents and sophisticated equipment. In this work, we show the proof of principle for single-molecule detection of the nucleocapsid protein 7 (NCp7), a protein biomarker of the HIV-1 virus, using synthetic nanopores and the resistive-pulse technique. The biosensing mechanism relied upon specific interactions between NCp7 and aptamers of stem-loop 3 (SL3) in the packaging domain of the retroviral RNA genome. One critical step of this study was the choice of the optimal size of the nanopores for accurate, label-free determinations of the dissociation constant of the NCp7 protein-SL3 RNA aptamer complex. Therefore, we systematically investigated the NCp7 protein-SL3 RNA aptamer complex employing two categories of nanopores in a silicon nitride membrane: (i) small, whose internal diameter was smaller than 6 nm, and (ii) large, whose internal diameter was in the range of 7 to 15 nm. Here, we demonstrate that only the use of nanopores with an internal diameter that is smaller than or comparable with the largest cross-sectional size of the NCp7-SL3 aptamer complex enables accurate measurement of the dissociation constant between the two interacting partners. Notably, this determination can be accomplished without the need for prior nanopore functionalization. Moreover, using small solid-state nanopores, we demonstrate the ability to detect drug candidates that inhibit the binding interactions between NCp7 and SL3 RNA by using a test case of N-ethylmaleimide.

Engineering a rigid protein tunnel for biomolecular detection

One intimidating challenge in protein nanopore-based technologies is designing robust protein scaffolds that remain functionally intact under a broad spectrum of detection conditions. Here, we show that an extensively engineered bacterial ferric hydroxamate uptake component A (FhuA), a β-barrel membrane protein, functions as a robust protein tunnel for the sampling of biomolecular events. The key implementation in this work was the coupling of direct genetic engineering with a refolding approach to produce an unusually stable protein nanopore. More importantly, this nanostructure maintained its stability under many experimental circumstances, some of which, including low ion concentration and highly acidic aqueous phase, are normally employed to gate, destabilize, or unfold β-barrel membrane proteins. To demonstrate these advantageous traits, we show that the engineered FhuA-based protein nanopore functioned as a sensing element for examining the proteolytic activity of an enzyme at highly acidic pH and for determining the kinetics of protein-DNA aptamer interactions at physiological salt concentration.

Comparative structural effects of HIV-1 Gag and nucleocapsid proteins in binding to and unwinding of the viral RNA packaging signal

The major RNA binding region of the HIV-1 Gag polyprotein is the nucleocapsid (NC) domain, which is responsible for the specific capture of the genomic RNA genome during viral assembly. The Gag polyprotein has other RNA chaperone functions, which are mirrored by the isolated NC protein after physiological cleavage from Gag. Gag, however, is suggested to have superior nucleic acid chaperone activity. Here we investigate the interaction of Gag and NC with the core RNA structure of the HIV-1 packaging signal (Ψ), using 2-aminopurine substitution to create a series of modified RNAs based on the Ψ helix loop structure. The effects of 2-aminopurine substitution on the physical and structural properties of the viral Ψ were characterized. The fluorescence properties of the 2-aminopurine substitutions showed features consistent with the native GNAR tetraloop. Dissociation constants (K(d)) of the two viral proteins, measured by fluorescence polarization (FP), were similar, and both NC and Gag affected the 2-aminopurine fluorescence of bases close to the loop binding region in a similar fashion. However, the influence of Gag on the fluorescence of the 2-aminopurine nucleotides at the base of the helix implied a much more potent helix destabilizing action on the RNA stem loop (SL) versus that seen with NC. This was further supported when the viral Ψ SL was tagged with a 5' fluorophore and 3' quencher. In the absence of any viral protein, minimal fluorescence was detected; addition of NC yielded a slight increase in fluorescence, while addition of the Gag protein yielded a large change in fluorescence, further suggesting that, compared to NC, the Gag protein has a greater propensity to affect RNA structure and that Ψ helix unwinding may be an intrinsic step in RNA encapsidation.

Importance of the NCp7-like domain in the recognition of pre-let-7g by the pluripotency factor Lin28

The pluripotency factor Lin28 is a highly conserved protein comprising a unique combination of RNA-binding motifs, an N-terminal cold-shock domain and a C-terminal region containing two retroviral-type CCHC zinc-binding domains. An important function of Lin28 is to inhibit the biogenesis of the let-7 family of microRNAs through a direct interaction with let-7 precursors. Here, we systematically characterize the determinants of the interaction between Lin28 and pre-let-7g by investigating the effect of protein and RNA mutations on in vitro binding. We determine that Lin28 binds with high affinity to the extended loop of pre-let-7g and that its C-terminal domain contributes predominantly to the affinity of this interaction. We uncover remarkable similarities between this C-terminal domain and the NCp7 protein of HIV-1, not only in terms of primary structure but also in their modes of RNA binding. This NCp7-like domain of Lin28 recognizes a G-rich bulge within pre-let-7g, which is adjacent to one of the Dicer cleavage sites. We hypothesize that the NCp7-like domain initiates RNA binding and partially unfolds the RNA. This partial unfolding would then enable multiple copies of Lin28 to bind the extended loop of pre-let-7g and protect the RNA from cleavage by the pre-microRNA processing enzyme Dicer.

Flexible nature and specific functions of the HIV-1 nucleocapsid protein

One salient feature of reverse transcription in retroviruses, notably in the human immunodeficiency virus type 1, is that it requires the homologous nucleocapsid (NC) protein acting as a chaperoning partner of the genomic RNA template and the reverse transcriptase, from the initiation to the completion of viral DNA synthesis. This short review on the NC protein of human immunodeficiency virus type 1 aims at briefly presenting the flexible nature of NC protein, how it interacts with nucleic acids via its invariant zinc fingers and flanking basic residues, and the possible mechanisms that account for its multiple functions in the early steps of virus replication, notably in the obligatory strand transfer reactions during viral DNA synthesis by the reverse transcriptase enzyme.

Structural determinants of TAR RNA-DNA annealing in the absence and presence of HIV-1 nucleocapsid protein

Annealing of the TAR RNA hairpin to the cTAR DNA hairpin is required for the minus-strand transfer step of HIV-1 reverse transcription. HIV-1 nucleocapsid protein (NC) plays a crucial role by facilitating annealing of the complementary hairpins. To gain insight into the mechanism of NC-mediated TAR RNA–DNA annealing, we used structural probes (nucleases and potassium permanganate), gel retardation assays, fluorescence anisotropy and cTAR mutants under conditions allowing strand transfer. In the absence of NC, cTAR DNA-TAR RNA annealing depends on nucleation through the apical loops. We show that the annealing intermediate of the kissing pathway is a loop–loop kissing complex involving six base-pairs and that the apical stems are not destabilized by this loop–loop interaction. Our data support a dynamic structure of the cTAR hairpin in the absence of NC, involving equilibrium between both the closed conformation and the partially open ‘Y’ conformation. This study is the first to show that the apical and internal loops of cTAR are weak and strong binding sites for NC, respectively. NC slightly destabilizes the lower stem that is adjacent to the internal loop and shifts the equilibrium toward the ‘Y’ conformation exhibiting at least 12 unpaired nucleotides in its lower part.

Molecular dynamics and DFT study on HIV-1 nucleocapsid protein-7 in complex with viral genome

The HIV-1 nucleocapsid protein-7 (NCp7) is a highly basic, small zinc-binding protein involved in both deoxyribonucleic (DNA) and ribonucleic (RNA) acids annealing and in viral particle maturation including genome encapsidation, with an additional chaperoning activity toward reverse transcriptase by promoting the two obligatory strand transfers during reverse transcription. Because of its interaction with highly conserved sequences of the HIV-1 genome, NCp7 is being considered a new potential drug target, resistant to mutation, for antiviral activity. The high flexibility of this protein has, however, limited the identification of structural determinants involved in the interaction with stranded sequences of DNA and RNA. Here, we provide a quantum mechanics (density functional theory) study of the zinc-binding motifs and a molecular dynamics simulation of the protein in complex with RNA and DNA, starting from available nuclear magnetic resonance (NMR) structures. Results show that the interaction between the NCp7 and the viral genome is probably based on electrostatic interactions due to a cluster of basic residues, which is reinforced by the exploitation of nonelectrostatic contacts that further stabilize the complexes. Moreover, a possible mechanism for DNA destabilization that involves amino acids T24 and R26 is also hypothesized. Finally, a network of hydrophobic and hydrogen-bond interactions for the stabilization of complexes with DNA and, especially, with RNA is described here for the first time. The complexes between NCp7 and both DNA and RNA, resulting from computer simulations, showed structural properties that are in agreement with most of the currently available molecular biology evidence and could be considered as reliable models (better than NMR structures currently available) for subsequent structure-based ligand design approaches.

Effects of the nature and concentration of salt on the interaction of the HIV-1 nucleocapsid protein with SL3 RNA

The mature nucleocapsid protein of HIV-1, NCp7, and the NC domains in gag precursors are attractive targets for anti-AIDS drug discovery. The stability of the 1:1 complex of NCp7 with a 20mer mimic of stem-loop 3 RNA (SL3, also called psi-RNA, in the packaging domain of genomic RNA) is strongly affected by changes in ionic strength. NC domains recognize and specifically package genomic HIV-1 RNA, while electrostatic attractions and high concentrations of protein and RNA drive NCp7 to completely coat the RNA in the mature virion. The specific interactions of NCp7 binding to loop bases of SL3 produce 1:1 complexes in solutions that have a NaCl concentration of >or=0.2 M, while the electrostatic interactions can dominate at <or=0.15 M NaCl, leading to complexes that have a mainly 1:2 RNA:protein ratio. Persistent, nonequilibrium mixtures of 1:1 and protein-excess complexes can exist at these lower salt concentrations, where the distribution of complexes depends on the order of addition of RNA and protein. Adding salt causes rapid rearrangement of metastable multiprotein complexes to a 1:1 ratio. The stability of complexes is also affected by the nature of the added salt, with 0.018 M MgCl(2) and added 0.200 M NaCl producing the same K(d) (21 +/- 2 nM); acetate ion stabilizes the 1:1 complex by a factor of more than 2 compared to the same concentration of chloride ion. Maintaining a salt concentration of 0.2 M NaCl or 18 mM MgCl(2) is sufficient for experiments to distinguish drug candidates that disrupt the specific SL3-NCp7 interactions in the 1:1 complex.

Site-specific characterization of HIV-1 nucleocapsid protein binding to oligonucleotides with two binding sites

The nucleocapsid protein (NC) of HIV-1 is a highly conserved protein essential for the virus life cycle that constitutes an attractive target for new antiviral agents. Most NC functions rely on its binding to the HIV-1 genomic RNA and its DNA copies that contain multiple and possibly interdependent binding sites. Therefore, a detailed understanding of NC binding requires a site-specific experimental approach. We have recently shown that 2-aminopurine (2Ap), a fluorescent adenine analogue, can site-selectively probe the binding of NC. Here, we introduced 2Ap at various positions of model single-stranded dodecanucleotides containing two TG motifs which constitute putative specific binding sites. Steady-state and time-resolved fluorescence experiments indicated that NC binding strongly increased the fluorescence quantum yield of 2AP by reducing the dynamic quenching of 2Ap by its close neighbors and slowing the picosecond to nanosecond conformational fluctuations of the oligonucleotides. The dodecanucleotides were found to bind two NC molecules at physiological salt concentrations, confirming the preferential binding of NC to TG motifs and an occluded binding site size for NC of five to six bases. Using the NC-induced changes in 2Ap fluorescence, we determined the microscopic affinity constants of the individual binding sites and showed that affinities can significantly differ from one site to another within the same dodecanucleotide, depending on the position of the TG dinucleotide and the nature of its close neighbors. Moreover, our data suggest that binding of NC even to close binding sites shows no strong cooperativity.

Effect of Mg(2+) and Na(+) on the nucleic acid chaperone activity of HIV-1 nucleocapsid protein: implications for reverse transcription

The human immunodeficiency virus type 1 (HIV-1) nucleocapsid protein (NC) is an essential protein for retroviral replication. Among its numerous functions, NC is a nucleic acid (NA) chaperone protein that catalyzes NA rearrangements leading to the formation of thermodynamically more stable conformations. In vitro, NC chaperone activity is typically assayed under conditions of low or no Mg(2+), even though reverse transcription requires the presence of divalent cations. Here, the chaperone activity of HIV-1 NC was studied as a function of varying Na(+) and Mg(2+) concentrations by investigating the annealing of complementary DNA and RNA hairpins derived from the trans-activation response domain of the HIV genome. This reaction mimics the annealing step of the minus-strand transfer process in reverse transcription. Gel-shift annealing and sedimentation assays were used to monitor the annealing kinetics and aggregation activity of NC, respectively. In the absence of protein, a limited ability of Na(+) and Mg(2+) cations to facilitate hairpin annealing was observed, whereas NC stimulated the annealing 10(3)- to 10(5)-fold. The major effect of either NC or the cations is on the rate of bimolecular association of the hairpins. This effect is especially strong under conditions wherein NC induces NA aggregation. Titration with NC and NC/Mg(2+) competition studies showed that the annealing kinetics depends only on the level of NA saturation with NC. NC competes with Mg(2+) or Na(+) for sequence-nonspecific NA binding similar to a simple trivalent cation. Upon saturation, NC induces attraction between NA molecules corresponding to approximately 0.3 kcal/mol/nucleotide, in agreement with an electrostatic mechanism of NC-induced NA aggregation. These data provide insights into the variable effects of NC's chaperone activity observed during in vitro studies of divalent metal-dependent reverse transcription reactions and suggest the feasibility of NC-facilitated proviral DNA synthesis within the mature capsid core.

Randomization and in vivo selection reveal a GGRG motif essential for packaging human immunodeficiency virus type 2 RNA

The packaging signal (psi) of human immunodeficiency virus type 2 (HIV-2) is present in the 5' noncoding region of RNA and contains a 10-nucleotide palindrome (pal; 5'-392-GGAGUGCUCC) located upstream of the dimerization signal stem-loop 1 (SL1). pal has been shown to be functionally important in vitro and in vivo. We previously showed that the 3' side of pal (GCUCC-3') is involved in base-pairing interactions with a sequence downstream of SL1 to make an extended SL1, which is important for replication in vivo and the regulation of dimerization in vitro. However, the role of the 5' side of pal (5'-GGAGU) was less clear. Here, we characterized this role using an in vivo SELEX approach. We produced a population of HIV-2 DNA genomes with random sequences within the 5' side of pal and transfected these into COS-7 cells. Viruses from COS-7 cells were used to infect C8166 permissive cells. After several weeks of serial passage in C8166 cells, surviving viruses were sequenced. On the 5' side of pal there was a striking convergence toward a GGRGN consensus sequence. Individual clones with consensus and nonconsensus sequences were tested in infectivity and packaging assays. Analysis of individuals that diverged from the consensus sequence showed normal viral RNA and protein synthesis but had replication defects and impaired RNA packaging. These findings clearly indicate that the GGRG motif is essential for viral replication and genomic RNA packaging.

How the HIV-1 nucleocapsid protein binds and destabilises the (-)primer binding site during reverse transcription

The human immunodeficiency virus type 1 nucleocapsid protein (NCp7) plays an important role in the second strand transfer during reverse transcription. It promotes annealing of the 18-nucleotide complementary DNA primer-binding site (PBS) sequences at the 3' ends of (-)DNA and (+)DNA. NMR studies show that NCp7(12-55) and NCp7(1-55) interact at the 5' end of the loop of DeltaP(-)PBS, a (-)PBS derivative without the 3' protruding sequence, in a slow-exchange equilibrium. This interaction is mediated through the binding of the hydrophobic plateau (Val13, Phe16, Thr24, Ala25, Trp37, and Met46) on the zinc finger domain of both peptides to the 5-CTG-7 sequence of DeltaP(-)PBS. The stacking of the Trp37 aromatic ring with the G7 residue likely constitutes the determinant factor of the interaction. Although NCp7(12-55) does not melt the DeltaP(-)PBS stem-loop structure, it opens the loop and weakens the C5.G11 base pair next to the loop. Moreover, NCp7(12-55) was also found to bind but with lower affinity to the 10-CGG-12 sequence in an intermediate-exchange equilibrium on the NMR time scale. The loop modifications may favour a kissing interaction with the complementary (+)PBS loop. Moreover, the weakening of the upper base pair of the stem likely promotes the melting of the stem that is required to convert the kissing complex into the final (+/-)PBS extended duplex.

Steric block high affinity oligonucleotide analogues: a new tool for mapping RNA-protein binding sites

Steric-block ON analogues are efficient inhibitors of RNA-protein interaction and therefore have potential to probe RNA sequences for putative protein binding sites and to investigate mechanisms of protein binding. The packaging process of HIV-1 is highly specific involving an interaction between the Gag protein and a conserved sequence that is only present on genomic viral RNA. Using oligonucleotide probes we have confirmed that the terminal purine loop is the major Gag binding site on SL3 and that a secondary Gag binding site exists at an internal purine bulge. We also demonstrate direct binding of oligonucleotide to their binding sites and confirm this interaction does not alter global RNA conformation, making them highly specific, nondisruptive probes of RNA protein interactions.

Role of the 5' TAR stem--loop and the U5-AUG duplex in dimerization of HIV-1 genomic RNA

The HIV-1 genome consists of two identical RNAs that are linked together through noncovalent interactions involving nucleotides from the 5' untranslated region (5' UTR) of each RNA strand. The 5' UTR is the most conserved part of the HIV-1 RNA genome, and its 335 nucleotide residues form regulatory motifs that mediate multiple essential steps in the viral replication cycle. Here, studying the effect of selected mutations both singly and together with mutations disabling SL1 (SL1 is a 5' UTR stem-loop containing a palindrome called the dimerization initiation site), we have done a rather systematic survey of the 5' UTR requirements for full genomic RNA dimerization in grown-up (i.e., predominantly >/=10 h old) HIV-1 viruses produced by transfected human and simian cells. We have identified a role for the 5' transactivation response element (5' TAR) and a contribution of a long-distance base pairing between a sequence located at the beginning of the U5 region and nucleotides surrounding the AUG Gag initiation codon. The resulting intra- or intermolecular duplex is called the U5-AUG duplex. The other regions of the 5' UTR have been shown to play no systematic role in genomic RNA dimerization, except for a sequence located around the 3' end of a large stem-loop enclosing the primer binding site, and the well-documented SL1. Our data are consistent with a direct role for the 5' TAR in genomic RNA dimerization (possibly via a palindrome encompassing the apical loop of the 5' TAR).

Biochemical approaches for characterizing RNA-protein complexes in preparation for high resolution structure analysis

RNA-protein interactions control viral RNA replication, transcription, translation, and particle assembly. Progress toward understanding the functional significance of RNA-protein complexes in the viral life cycle is hindered by the lack of high resolution structural information. Challenges to acquiring structural data include RNA's inherent instability and conformational plasticity, coupled with the comparatively high cost of generating large quantities of RNA for biophysical experiments. The potential for successful structure determination is increased by conducting biochemical experiments that outline interacting domains and identify key residues. These approaches are aimed at defining and characterizing RNA and protein substrates that are suitable for high resolution structural analysis.

Structural requirements for nucleocapsid protein-mediated dimerization of avian leukosis virus RNA

The avian leukosis virus (ALV) belongs to the alpha group of retroviruses that are widespread in nature. The 5'-untranslated region of ALV genome contains the L3 element that is important for virus infectivity and the formation of an unstable RNA dimer in vitro. The L3 sequence is predicted to fold into a long stem-loop structure with two internal loops and an apical one. Phylogenetic analysis predicts that the L3 stem-loop is conserved in alpharetroviruses. Furthermore, a significant selection mechanism maintains a palindrome in the apical loop. The nucleocapsid protein of the alpharetroviruses (NCp12) is required for RNA dimer formation and replication in vivo. It is not known whether L3 can be an NCp12-mediated RNA dimerization site able to bind NCp12 with high affinity. Here, we report that NCp12 chaperones formation of a stable ALV RNA dimer through L3. To investigate the NCp12-mediated L3 dimerization reaction, we performed site-directed mutagenesis, gel retardation and heterodimerization assays and analysis of thermostability of dimeric RNAs. We show that the affinity of NCp12 for L3 is lower than its affinity for the microPsi RNA packaging signal. Results show that conservation of a long stem-loop structure and a loop-loop interaction are not required for NCp12-mediated L3 dimerization. We show that the L3 apical stem-loop is sufficient to form an extended duplex and the whole stem-loop L3 cannot be converted by NCp12 into a duplex extending throughout L3. Three-dimensional modelling of the stable L3 dimer supports the notion that the extended duplex may represent the minimal dimer linkage structure found in the genomic RNA.

RNA and DNA binding properties of HIV-1 Vif protein: a fluorescence study

The HIV-1 viral infectivity factor (Vif) is a small basic protein essential for viral fitness and pathogenicity. Some "non-permissive" cell lines cannot sustain replication of Vif(-) HIV-1 virions. In these cells, Vif counteracts the natural antiretroviral activity of the DNA-editing enzymes APOBEC3G/3F. Moreover, Vif is packaged into viral particles through a strong interaction with genomic RNA in viral nucleoprotein complexes. To gain insights into determinants of this binding process, we performed the first characterization of Vif/nucleic acid interactions using Vif intrinsic fluorescence. We determined the affinity of Vif for RNA fragments corresponding to various regions of the HIV-1 genome. Our results demonstrated preferential and moderately cooperative binding for RNAs corresponding to the 5'-untranslated region of HIV-1 (5'-untranslated region) and gag (cooperativity parameter omega approximately 65-80, and K(d) = 45-55 nM). In addition, fluorescence spectroscopy allowed us to point out the TAR apical loop and a short region in gag as primary strong affinity binding sites (K(d) = 9.5-14 nM). Interestingly, beside its RNA binding properties, the Vif protein can also bind the corresponding DNA oligonucleotides and their complementary counterparts with an affinity similar to the one observed for the RNA sequences, while other DNA sequences displayed reduced affinity. Taken together, our results suggest that Vif binding to RNA and DNA offers several non-exclusive ways to counteract APOBEC3G/3F factors, in addition to the well documented Vif-induced degradation by the proteasome and to the Vif-mediated repression of translation of these antiviral factors.

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

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.

NMR structure of the full-length linear dimer of stem-loop-1 RNA in the HIV-1 dimer initiation site

The packaging signal of HIV-1 RNA contains a stem-loop structure, SL1, which serves as the dimerization initiation site for two identical copies of the genome and is important for packaging of the RNA genome into the budding virion and for overall infectivity. SL1 spontaneously dimerizes via a palindromic hexanucleotide sequence in its apical loop, forming a metastable kissing dimer form. Incubation with nucleocapsid protein causes this form to refold to a thermodynamically stable mature linear dimer. Here, we present an NMR structure of the latter form of the full-length SL1 sequence of the Lai HIV-1 isolate. The structure was refined using nuclear Overhauser effect and residual dipolar coupling data. The structure presents a symmetric homodimer of two RNA strands of 35 nucleotides each; it includes five stems separated by four internal loops. The central palindromic stem is surrounded by two symmetric adenine-rich 1-2 internal loops, A-bulges. All three adenines in each A-bulge are stacked inside the helix, consistent with the solution structures of shorter SL1 constructs determined previously. The outer 4-base pair stems and, proximal to them, purine-rich 1-3 internal loops, or G-bulges, are the least stable parts of the molecule. The G-bulges display high conformational variability in the refined ensemble of structures, despite the availability of many structural restraints for this region. Nevertheless, most conformations share a similar structural motif: a guanine and an adenine from opposite strands form a GA mismatch stacked on the top of the neighboring stem. The two remaining guanines are exposed, one in the minor groove and another in the major groove side of the helix, consistent with secondary structure probing data for SL1. These guanines may be recognized by the nucleocapsid protein, which binds tightly to the G-bulge in vitro.

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.

Combinatorial selection, inhibition, and antiviral activity of DNA thioaptamers targeting the RNase H domain of HIV-1 reverse transcriptase

Despite the key role played by the RNase H of human immunodeficiency virus-1 reverse transcriptase (HIV-1 RT) in viral proliferation, only a few inhibitors of RNase H have been reported. Using in vitro combinatorial selection methods and the RNase H domain of the HIV RT, we have selected double-stranded DNA thioaptamers (aptamers with selected thiophosphate backbone substitutions) that inhibit RNase H activity and viral replication. The selected thioaptamer sequences had a very high proportion of G residues. The consensus sequence for the selected thioaptamers showed G clusters separated by single residues at the 5'-end of the sequence. Gel electrophoresis mobility shift assays and nuclear magnetic resonance spectroscopy showed that the selected thioaptamer binds to the isolated RNase H domain, but did not bind to a structurally similar RNase H from Escherichia coli. The lead thioaptamer, R12-2, showed specific binding to HIV-1 RT with a binding constant (K(d)) of 70 nM. The thioaptamer inhibited the RNase H activity of intact HIV-1 RT. In cell culture, transfection of thioaptamer R12-2 (0.5 microg/mL) markedly inhibited viral production and exhibited a dose response of inhibition with R12-2 concentrations ranging from 0.03 to 2.0 microg/mL (IC(50) < 100 nM). Inhibition was also seen across a wide range of virus inoculum, ranging from a multiplicity of infection (moi) of 0.0005 to 0.05, with a reduction of the level of virus production by more than 50% at high moi. Suppression of virus was comparable to that seen with AZT when moi <or= 0.005.

Cooperative and specific binding of Vif to the 5' region of HIV-1 genomic RNA

The viral infectivity factor (Vif) protein of human immunodeficiency virus type 1 (HIV-1) is essential for viral replication in vivo. Packaging of Vif into viral particles is mediated by an interaction with viral genomic RNA and association with viral nucleoprotein complexes. Despite recent findings on the RNA-binding properties of Vif suggesting that Vif could be involved in retroviral assembly, no RNA sequence or structure specificity has been determined so far. To gain further insight into the mechanisms by which Vif might regulate viral replication, we studied the interactions of Vif with HIV-1 genomic RNA in vitro. Using extensive biochemical analysis, we have measured the affinity of recombinant Vif proteins for synthetic RNAs corresponding to various regions of the HIV-1 genome. We found that recombinant Vif proteins bind specifically to HIV-1 viral RNA fragments corresponding to the 5'-untranslated region (5'-UTR), gag and the 5' part of pol (K(d) between 45 nM and 65 nM). RNA encompassing nucleotides 1-497 or 499-996 of the HIV-1 genomic RNA bind 9+/-2 and 21+/-3 Vif molecules, respectively, and at least some of these proteins bind in a cooperative manner (Hill constant alpha(H) = 2.3). In contrast, RNAs corresponding to other parts of the HIV-1 genome or heterologous RNAs showed poor binding capacity and weak cooperativity (K(d) > 200 nM). Moreover, RNase T1 footprinting revealed a hierarchical binding of Vif, pointing to TAR and the poly(A) stem-loop structures as primary strong affinity targets, and downstream structures as secondary sites with moderate affinity. Taken together, our findings suggest that Vif may assist other proteins to maintain a correct folding of the genomic RNA in order to facilitate its packaging and further steps such as reverse transcription. Interestingly, our results suggest also that Vif could bind the viral RNA in order to protect it from the action of the antiviral factor APOBEC-3G/3F.

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.

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.