HIV Rev-isited.

The human immunodeficiency virus type 1 (HIV-1) proteome is expressed from alternatively spliced and unspliced genomic RNAs. However, HIV-1 RNAs that are not fully spliced are perceived by the host machinery as defective and are retained in the nucleus. During late infection, HIV-1 bypasses this regulatory mechanism by expression of the Rev protein from a fully spliced mRNA. Once imported into the nucleus, Rev mediates the export of unprocessed HIV-1 RNAs to the cytoplasm, leading to the production of the viral progeny. While regarded as a canonical RNA export factor, Rev has also been linked to HIV-1 RNA translation, stabilization, splicing and packaging. However, Rev's functions beyond RNA export have remained poorly understood. Here, we revisit this paradigmatic protein, reviewing recent data investigating its structure and function. We conclude by asking: what remains unknown about this enigmatic viral protein?

The Jembrana disease virus Rev protein: Identification of nuclear and novel lentiviral nucleolar localization and nuclear export signals.

The lentiviral Rev protein, which is a regulatory protein essential for virus replication, has been first studied in the human immunodeficiency virus type 1 (HIV-1). The main function of Rev is to mediate the nuclear exportation of viral RNAs. To fulfill its function, Rev shuttles between the cytoplasm and the nucleus. The Jembrana disease virus (JDV), a lentivirus, is the etiologic agent of the Jembrana disease which was first described in Bali cattle in Indonesia in 1964. Despite the high mortality rate associated with JDV, this virus remains poorly studied. Herein the subcellular distribution of JDV Rev, the nuclear and nucleolar localization signals (NLS and NoLS, respectively) and the nuclear export signal (NES) of the protein were examined. JDV Rev fused to the enhanced green fluorescent protein (EGFP) predominantly localized to the cytoplasm and nucleolus of transfected cells, as determined by fluorescence microscopy analyses. Through transfection of a series of deletion mutants of JDV Rev, it was possible to localize the NLS/NoLS region between amino acids (aa) 74 to 105. By substituting basic residues with alanine within this sequence, we demonstrated that the JDV Rev NLS encompasses aa 76 to 86, and is exclusively composed of arginine residues, whereas a bipartite NoLS was observed for the first time in any retroviral Rev/Rev-like proteins. Finally, a NES was identified downstream of the NLS/NoLS and encompasses aa 116 to 128 of the JDV Rev protein. The JDV Rev NES was found to be of the protein kinase A inhibitor (PKI) class instead of the HIV-1 Rev class. It also corresponds to the most optimal consensus sequence of PKI NES and, as such, is novel among lentiviral Rev NES.

Multifunctional Enzyme Packaging and Catalysis in the Qß Protein Nanoparticle.

The simultaneous expression in Escherichia coli cells of the Qß virus-like particle (VLP) capsid protein and protein "cargo" tagged with a positively charged Rev peptide sequence leads to the spontaneous self-assembly of VLPs with multiple copies of the cargo inside. We report the packaging of four new enzymes with potential applications in medicine and chemical manufacturing. The captured enzymes are active while inside the nanoparticle shell and are protected from environmental conditions that lead to free-enzyme destruction. We also describe genetic modifications to the packaging scheme that shed light on the self-assembly mechanism of this system and allow indirect control over the internal packaging density of cargo. The technology was extended to create, via self-assembly, VLPs that simultaneously display protein ligands on the exterior and contain enzymes within. Inverse relationships were observed between the size of both the packaged and externally displayed protein or domains and nanoparticle yield. These results provide a general method for the rapid creation of robust protein nanoparticles with desired catalytic and targeting functionalities.

Identification of a homogenous structural basis for oligomerization by retroviral Rev-like proteins.

BACKGROUND: Rev-like proteins are post-transcriptional regulatory proteins found in several retrovirus genera, including lentiviruses, betaretroviruses, and deltaretroviruses. These essential proteins mediate the nuclear export of incompletely spliced viral RNA, and act by tethering viral pre-mRNA to the host CRM1 nuclear export machinery. Although all Rev-like proteins are functionally homologous, they share less than 30% sequence identity. In the present study, we computationally assessed the extent of structural homology among retroviral Rev-like proteins within a phylogenetic framework. RESULTS: We undertook a comprehensive analysis of overall protein domain architecture and predicted secondary structural features for representative members of the Rev-like family of proteins. Similar patterns of α-helical domains were identified for Rev-like proteins within each genus, with the exception of deltaretroviruses, which were devoid of α-helices. Coiled-coil oligomerization motifs were also identified for most Rev-like proteins, with the notable exceptions of HIV-1, the deltaretroviruses, and some small ruminant lentiviruses. In Rev proteins of primate lentiviruses, the presence of predicted coiled-coil motifs segregated within specific primate lineages: HIV-1 descended from SIVs that lacked predicted coiled-coils in Rev whereas HIV-2 descended from SIVs that contained predicted coiled-coils in Rev. Phylogenetic ancestral reconstruction of coiled-coils for all Rev-like proteins predicted a single origin for the coiled-coil motif, followed by three losses of the predicted signal. The absence of a coiled-coil signal in HIV-1 was associated with replacement of canonical polar residues with non-canonical hydrophobic residues. However, hydrophobic residues were retained in the key 'a' and 'd' positions, and the α-helical region of HIV-1 Rev oligomerization domain could be modeled as a helical wheel with two predicted interaction interfaces. Moreover, the predicted interfaces mapped to the dimerization and oligomerization interfaces in HIV-1 Rev crystal structures. Helical wheel projections of other retroviral Rev-like proteins, including endogenous sequences, revealed similar interaction interfaces that could mediate oligomerization. CONCLUSIONS: Sequence-based computational analyses of Rev-like proteins, together with helical wheel projections of oligomerization domains, reveal a conserved homogeneous structural basis for oligomerization by retroviral Rev-like proteins.

The interaction of RNA helicase DDX3 with HIV-1 Rev-CRM1-RanGTP complex during the HIV replication cycle.

Molecular traffic between the nucleus and the cytoplasm is regulated by the nuclear pore complex (NPC), which acts as a highly selective channel perforating the nuclear envelope in eukaryotic cells. The human immunodeficiency virus (HIV) exploits the nucleocytoplasmic pathway to export its RNA transcripts across the NPC to the cytoplasm. Despite extensive study on the HIV life cycle and the many drugs developed to target this cycle, no current drugs have been successful in targeting the critical process of viral nuclear export, even though HIV's reliance on a single host protein, CRM1, to export its unspliced and partially spliced RNA transcripts makes it a tempting target. Due to recent findings implicating a DEAD-box helicase, DDX3, in HIV replication and a member of the export complex, it has become an appealing target for anti-HIV drug inhibition. In the present research, we have applied a hybrid computational protocol to analyze protein-protein interactions in the HIV mRNA export cycle. This method is based on molecular docking followed by molecular dynamics simulation and accompanied by approximate free energy calculation (MM/GBSA), computational alanine scanning, clustering, and evolutionary analysis. We highlight here some of the most likely binding modes and interfacial residues between DDX3 and CRM1 both in the absence and presence of RanGTP. This work shows that although DDX3 can bind to free CRM1, addition of RanGTP leads to more concentrated distribution of binding modes and stronger binding between CRM1 and RanGTP.

Computational modeling suggests dimerization of equine infectious anemia virus Rev is required for RNA binding.

BACKGROUND: The lentiviral Rev protein mediates nuclear export of intron-containing viral RNAs that encode structural proteins or serve as the viral genome. Following translation, HIV-1 Rev localizes to the nucleus and binds its cognate sequence, termed the Rev-responsive element (RRE), in incompletely spliced viral RNA. Rev subsequently multimerizes along the viral RNA and associates with the cellular Crm1 export machinery to translocate the RNA-protein complex to the cytoplasm. Equine infectious anemia virus (EIAV) Rev is functionally homologous to HIV-1 Rev, but shares very little sequence similarity and differs in domain organization. EIAV Rev also contains a bipartite RNA binding domain comprising two short arginine-rich motifs (designated ARM-1 and ARM-2) spaced 79 residues apart in the amino acid sequence. To gain insight into the topology of the bipartite RNA binding domain, a computational approach was used to model the tertiary structure of EIAV Rev. RESULTS: The tertiary structure of EIAV Rev was modeled using several protein structure prediction and model quality assessment servers. Two types of structures were predicted: an elongated structure with an extended central alpha helix, and a globular structure with a central bundle of helices. Assessment of models on the basis of biophysical properties indicated they were of average quality. In almost all models, ARM-1 and ARM-2 were spatially separated by >15 Å, suggesting that they do not form a single RNA binding interface on the monomer. A highly conserved canonical coiled-coil motif was identified in the central region of EIAV Rev, suggesting that an RNA binding interface could be formed through dimerization of Rev and juxtaposition of ARM-1 and ARM-2. In support of this, purified Rev protein migrated as a dimer in Blue native gels, and mutation of a residue predicted to form a key coiled-coil contact disrupted dimerization and abrogated RNA binding. In contrast, mutation of residues outside the predicted coiled-coil interface had no effect on dimerization or RNA binding. CONCLUSIONS: Our results suggest that EIAV Rev binding to the RRE requires dimerization via a coiled-coil motif to juxtapose two RNA binding motifs, ARM-1 and ARM-2.

The bovine immunodeficiency virus Rev protein: identification of a novel nuclear import pathway and nuclear export signal among retroviral Rev/Rev-like proteins.

The Rev protein is essential for the replication of lentiviruses. Rev is a shuttling protein that transports unspliced and partially spliced lentiviral RNAs from the nucleus to the cytoplasm via the nucleopore. To transport these RNAs, the human immunodeficiency virus type 1 (HIV-1) Rev uses the karyopherin ß family importin ß and CRM1 proteins that interact with the Rev nuclear localization signal (NLS) and nuclear exportation signal (NES), respectively. Recently, we reported the presence of new types of bipartite NLS and nucleolar localization signal (NoLS) in the bovine immunodeficiency virus (BIV) Rev protein. Here we report the characterization of the nuclear import and export pathways of BIV Rev. By using an in vitro nuclear import assay, we showed that BIV Rev is transported into the nucleus by a cytosolic and energy-dependent importin α/ß classical pathway. Results from glutathione S-transferase (GST) pulldown assays that showed the binding of BIV Rev with importins α3 and α5 were in agreement with those from the nuclear import assay. We also identified a leptomycin B-sensitive NES in BIV Rev, which indicates that the protein is exported via CRM1 like HIV-1 Rev. Mutagenesis experiments showed that the BIV Rev NES maps between amino acids 109 to 121 of the protein. Remarkably, the BIV Rev NES was found to be of the cyclic AMP (cAMP)-dependent protein kinase inhibitor (PKI) type instead of the HIV-1 Rev type. In summary, our data showed that the nuclear import mechanism of BIV Rev is novel among Rev proteins characterized so far in lentiviruses.

Targeted cleavage of HIV RRE RNA by Rev-coupled transition metal chelates.

A series of compounds that target reactive metal chelates to the HIV-1 Rev response element (RRE) mRNA have been synthesized. Dissociation constants and chemical reactivity toward HIV RRE RNA have been determined and evaluated in terms of reduction potential, coordination unsaturation, and overall charge associated with the metal-chelate-Rev complex. Ethylenediaminetetraacetic acid (EDTA), nitrilotriacetic acid (NTA), diethylenetriaminepentaacetic acid (DTPA), and 1,4,7,10-tetraazacyclododecane-1,4,7,10-tetraacetic acid (DOTA) were linked to a lysine side chain of a Rev-derived peptide by either EDC/NHS or isothiocyanate coupling. The resulting chelate-Rev (EDTA-Rev, DTPA-Rev, NTA-Rev, and DOTA-Rev) conjugates were used to form coordination complexes with Fe(2+), Co(2+), Ni(2+), and Cu(2+) such that the arginine-rich Rev peptide could mediate localization of the metal chelates to the Rev peptide's high-affinity mRNA binding partner, RRE stem loop IIB. Metal complexes of the extended peptides GGH-Rev and KGHK-Rev, which also contain N-terminal peptidic chelators (ATCUN motifs), were studied for comparison. A fluorescence titration assay revealed high-affinity RRE RNA binding by all 22 metal-chelate-Rev species, with K(D) values ranging from ~0.2 to 16 nM, indicating little to no loss of RNA affinity due to the coupling of the metal chelates to the Rev peptide. Dissociation constants for binding at a previously unobserved low-affinity site are also reported. Rates of RNA modification by each metal-chelate-Rev species were determined and varied from ~0.28 to 4.9 nM/min but were optimal for Cu(2+)-NTA-Rev. Metal-chelate reduction potentials were determined and varied from -228 to +1111 mV vs NHE under similar solution conditions, allowing direct comparison of reactivity with redox thermodynamics. Optimal activity was observed when the reduction potential for the metal center was poised between those of the two principal co-reagents for metal-promoted formation of reactive oxygen species: E°(ascorbate/ascorbyl radical) = -66 mV and E°(H(2)O(2)/hydroxyl radical) = 380 mV. Given the variety of oxidative activities of these metal complexes and their high-affinity binding to the targeted RRE mRNA following coupling to the Rev peptide, this class of metal-chelate-Rev derivatives constitutes a promising step toward development of multiple-turnover reagents for selective eradication of HIV-1 RRE mRNA.

HIV Rev response element (RRE) directs assembly of the Rev homooligomer into discrete asymmetric complexes.

RNA is a crucial structural component of many ribonucleoprotein (RNP) complexes, including the ribosome, spliceosome, and signal recognition particle, but the role of RNA in guiding complex formation is only beginning to be explored. In the case of HIV, viral replication requires assembly of an RNP composed of the Rev protein homooligomer and the Rev response element (RRE) RNA to mediate nuclear export of unspliced viral mRNAs. Assembly of the functional Rev-RRE complex proceeds by cooperative oligomerization of Rev on the RRE scaffold and utilizes both protein-protein and protein-RNA interactions to organize complexes with high specificity. The structures of the Rev protein and a peptide-RNA complex are known, but the complete RNP is not, making it unclear to what extent RNA defines the composition and architecture of Rev-RNA complexes. Here we show that the RRE controls the oligomeric state and solubility of Rev and guides its assembly into discrete Rev-RNA complexes. SAXS and EM data were used to derive a structural model of a Rev dimer bound to an essential RRE hairpin and to visualize the complete Rev-RRE RNP, demonstrating that RRE binding drives assembly of Rev homooligomers into asymmetric particles, reminiscent of the role of RNA in organizing more complex RNP machines, such as the ribosome, composed of many different protein subunits. Thus, the RRE is not simply a passive scaffold onto which proteins bind but instead actively defines the protein composition and organization of the RNP.

An intrabody based on a llama single-domain antibody targeting the N-terminal alpha-helical multimerization domain of HIV-1 rev prevents viral production.

The human immunodeficiency virus, type 1 (HIV-1)-encoded Rev protein is essential for the expression of late viral mRNAs. Rev forms a large organized multimeric protein-protein complex on the Rev response element of these viral mRNA species and transports them from the nucleus to the cytoplasm, exploiting the CRM1-mediated cellular machinery. Here we report the selection of a nanobody, derived from a llama heavy-chain only antibody, that efficiently blocks the assembly of Rev multimers. The nanobody inhibits HIV-1 replication in cells and specifically suppresses the Rev-dependent expression of partially spliced and unspliced HIV-1 RNA. In HIV-susceptible cells, this nanobody thus has potential as an effective anti-HIV agent using genetic immunization strategies. Its binding site was mapped to Rev residues Lys-20 and Tyr-23 located in the N-terminal alpha-helical multimerization domain. In the presence of this nanobody, we observed an accumulation of dimeric Rev species, supporting a head-to-head/tail-to-tail molecular model for Rev assembly. The results indicate that the oligomeric assembly of Rev follows an ordered stepwise process and identify a new epitope within Rev that could guide strategies for the development of novel HIV inhibitors.

The bovine immunodeficiency virus rev protein: identification of a novel lentiviral bipartite nuclear localization signal harboring an atypical spacer sequence.

The bovine immunodeficiency virus (BIV) Rev protein (186 amino acids [aa] in length) is involved in the nuclear exportation of partially spliced and unspliced viral RNAs. Previous studies have shown that BIV Rev localizes in the nucleus and nucleolus of infected cells. Here we report the characterization of the nuclear/nucleolar localization signals (NLS/NoLS) of this protein. Through transfection of a series of deletion mutants of BIV Rev fused to enhanced green fluorescent protein and fluorescence microscopy analyses, we were able to map the NLS region between aa 71 and 110 of the protein. Remarkably, by conducting alanine substitution of basic residues within the aa 71 to 110 sequence, we demonstrated that the BIV Rev NLS is bipartite, maps to aa 71 to 74 and 95 to 101, and is predominantly composed of arginine residues. This is the first report of a bipartite Rev (or Rev-like) NLS in a lentivirus/retrovirus. Moreover, this NLS is atypical, as the length of the sequence between the motifs composing the bipartite NLS, e.g., the spacer sequence, is 20 aa. Further mutagenesis experiments also identified the NoLS region of BIV Rev. It localizes mainly within the NLS spacer sequence. In addition, the BIV Rev NoLS sequence differs from the consensus sequence reported for other viral and cellular nucleolar proteins. In summary, we conclude that the nucleolar and nuclear localizations of BIV Rev are mediated via novel NLS and NoLS motifs.

Thermodynamic profiling of HIV RREIIB RNA-zinc finger interactions.

The interactions between the HIV Rev-responsive element (RRE) RNA and the HIV regulatory protein Rev, are crucial for the HIV life-cycle. Earlier, we showed that single C(2)H(2) zinc fingers (znfs) have the same binding site as the Rev peptide and exhibit nanomolar affinity. In this study, the specific role of amino acid side chains and molecular processes involved with complex formation were investigated by perturbation of the binding energetics via changes in temperature, pH, buffers, and salt concentrations, as well as znf and RNA mutations, by isothermal titration calorimetry. Interestingly, despite the large cationic charge on the znfs, the number of interactions with the RNA phosphate backbone was lower than intuitively expected. The presence of binding induced protonation was established by ITC and localized by NMR to a histidine on the znf beta-sheet. The DeltaC(p) of znf-RNA binding was observed to be substantially negative and could not be accounted for by conventional solvent-accessible surface area models. An alternative model, based on the extent of hydrogen bond changes as a result of differences in ligand-induced water displacement at the binding site, provided reasonable explanation of the trends in DeltaC(p), as well as DeltaH and DeltaS. Our studies show that incorporation of favorable interactions at the solvent-excluded binding interface can be used to alleviate the unfavorable enthalpic penalties of displacing water molecules from the hydrated RNA surface.

Structural model of the Rev regulatory protein from equine infectious anemia virus.

Rev is an essential regulatory protein in the equine infectious anemia virus (EIAV) and other lentiviruses, including HIV-1. It binds incompletely spliced viral mRNAs and shuttles them from the nucleus to the cytoplasm, a critical prerequisite for the production of viral structural proteins and genomic RNA. Despite its important role in production of infectious virus, the development of antiviral therapies directed against Rev has been hampered by the lack of an experimentally-determined structure of the full length protein. We have used a combined computational and biochemical approach to generate and evaluate a structural model of the Rev protein. The modeled EIAV Rev (ERev) structure includes a total of 6 helices, four of which form an anti-parallel four-helix bundle. The first helix contains the leucine-rich nuclear export signal (NES). An arginine-rich RNA binding motif, RRDRW, is located in a solvent-exposed loop region. An ERLE motif required for Rev activity is predicted to be buried in the core of modeled structure where it plays an essential role in stabilization of the Rev fold. This structural model is supported by existing genetic and functional data as well as by targeted mutagenesis of residues predicted to be essential for overall structural integrity. Our predicted structure should increase understanding of structure-function relationships in Rev and may provide a basis for the design of new therapies for lentiviral diseases.

Controlling a substrate-binding geometry of ribonucleopeptide receptor.

We describe here a novel strategy to create a ribonucleopeptide (RNP) receptor with defined substrate-binding geometry. RNP library was generated by introducing randomized nucleotide sequences in the RNA subunit of the structurally well-defined complex of RRE-RNA and the Rev peptide by a structure-based design. ATP-binding RNP receptors were selected from the RNP library by in vitro selection. The ATP-binding RNP receptors had RNA sequences varying in the location of the consensus sequence within the randomized nucleotide region. Each RNA subunit was expected to form a ligand-binding pocket with a unique geometry to the N-terminal of the Rev peptide. We have developed a selection strategy to select an ATP-binding receptor with a defined binding geometry by utilizing an ATP-Rev peptide conjugate.

Construction of ribonucleopeptide-based fluorescent sensors for biologically active amines.

Fluorescent biosensors are expected to be utilized for a wide range of applications, such as diagnostic and pharmacological tools. However, fluorescent biosensors synthesized by the direct coupling between the ligand bindings and optical signalling events are not always guaranteed to execute the expected optical signals. Our strategy of the stepwise molding using a framework of ribonucleopeptide (RNP) provides fluorescent biosensors with a variety of binding and signal-transducing characteristics for small molecules. RNP-based fluorescent sensors were created with a combination of in vitro selection method and a successive modification of the peptide of RNP with a fluorophore. The RNP containing the fluorophore labeled peptide subunit showed a remarkable fluorescence emission change upon binding to biologically active amines.

Potent inhibition of HIV-1 replication by backbone cyclic peptides bearing the Rev arginine rich motif.

Due to its essential role in the virus life cycle, the viral regulatory protein Rev constitutes an attractive target for the development of new antiviral molecules. In this work, a series of Backbone Cyclic Peptide (BCP) analogs that bear a conformationally constrained arginine rich motif (ARM) of Rev were tested for in vitro inhibition of HIV-1 replication. We observed a potent suppression of HIV-1 replication in chronically infected T lymphocytic cells treated with Rev-BCPs. We further investigated possible mechanisms of HIV-1 inhibition and showed that Rev-BCPs interfere slightly with the nuclear import process and are very efficient in blocking a mechanism that controls Pr55(gag) and gp160(env) synthesis. Interestingly, these protein precursors are known to be encoded by mRNAs that require Rev-binding for nuclear export. In situ hybridization using a Cy-3 conjugated HIV-1 gag oligonucleotide probe indicated that Rev-BCPs prevent the intracellular accumulation of unspliced viral RNA. As a model, the most promising analog, Rev-BCP 14, was studied by molecular modeling and dynamics in order to identify its binding site on the Rev Response Element (RRE). The annealing simulation suggests that upon binding on the RRE, Rev-BCP 14 widens the distorted major groove of the viral RNA. Numerous contacts between peptide and RNA were found within the complex and some were identified as key components for the interactions. Altogether, our data indicate that the use of conformationally constrained Rev-BCPs represents a promising strategy for the development of new peptide-based therapeutic agents against HIV-1.

Interaction between HIV-1 Rev and integrase proteins: a basis for the development of anti-HIV peptides.

Human immunodeficiency virus 1 (HIV-1) Rev and integrase (IN) proteins are required within the nuclei of infected cells in the late and early phases of the viral replication cycle, respectively. Here we show using various biochemical methods, that these two proteins interact with each other in vitro and in vivo. Peptide mapping and fluorescence anisotropy showed that IN binds residues 1-30 and 49-74 of Rev. Following this observation, we identified two short Rev-derived peptides that inhibit the 3'-end processing and strand-transfer enzymatic activities of IN in vitro. The peptides bound IN in vitro, penetrated into cultured cells, and significantly inhibited HIV-1 in multinuclear activation of a galactosidase indicator (MAGI) and lymphoid cultured cells. Real time PCR analysis revealed that the inhibition of HIV-1 multiplication is due to inhibition of the catalytic activity of the viral IN. The present work describes novel anti-HIV-1 lead peptides that inhibit viral replication in cultured cells by blocking DNA integration in vivo.

Construction of intramolecular luciferase complementation probe for detecting specific RNA.

Intermolecular enzyme complementation assay is a useful method for detecting protein-protein interactions. Specifically, bioluminescent signals produced from reconstructed split luciferase fragments are powerful tools for in vivo analysis because the bioluminescent signals have been visualized both in cultured cells and living animals. However, they are limited for detection and evaluation of biological events relevant to intermolecular protein-protein interactions. In this study, we constructed an intramolecular luciferase complementation probe for detecting target biomolecules other than protein-protein interactions. It consists of peptide-inserted firefly luciferase (PI-FLuc) containing a short peptide between internally divided firefly luciferase. The inserted short peptide triggers FLuc complementation or discomplementation and subsequent reactivation or inactivation of FLuc activity through its induced fit conformational changes. We chose RNA binding arginine rich motif (ARM) peptides, Rev and/or Tat, for model peptide insertion, and expressed constructed PI-FLuc probe variants using a wheat germ cell-free protein synthesis system. They showed FLuc activity changes, reactivation, or inactivation after binding to their specific RNA targets. Furthermore, to expand the versatility of the PI-FLuc RNA detection system, we designed split-RNA probes built to reform the ARM peptide binding site in the presence of arbitrarily selected target-RNA. As a result, the target RNA was homogeneously detected by FLuc luminescent signals mediated by a cooperative function of the PI-FLuc and split-RNA probe sets.

Constraints on protein structure in HIV-1 Rev and Rev-RNA supramolecular assemblies from two-dimensional solid state nuclear magnetic resonance.

The HIV-1 Rev protein is required for export of partially spliced and unspliced viral mRNA from nuclei of infected cells, and ultimately for viral replication. Rev is highly prone to aggregation, both in the absence and in the presence of the Rev responsive element (RRE) RNA to which it binds. As a result, the full molecular structures of Rev and Rev-RRE complexes are not known. We describe the results of transmission electron microscopy, atomic force microscopy, and solid state nuclear magnetic resonance (NMR) experiments on pure Rev filaments and coassemblies of Rev with a 45-base RNA sequence representing the high-affinity stem-loop IIB segment of the RRE. The morphologies of Rev filaments and Rev-RNA coassemblies are qualitatively different. Nonetheless, two-dimensional (2D) solid state 13C-13C NMR spectra of Rev filament and Rev-RNA coassembly samples, in which all Ile, Val, and Ala residues are uniformly labeled with 13C, are nearly indistinguishable, indicating that the protein conformation is essentially the same in the two types of supramolecular assemblies. Analysis of cross-peak patterns in the 2D spectra supports a previously developed helix-loop-helix structural model for the N-terminal half of Rev and shows that this model applies to both Rev filaments and Rev-RNA coassemblies. In addition, the 2D spectra suggest the presence of additional helix content at Ile and Val sites in the C-terminal half of Rev.