Analysis of the EIAV Rev-responsive element (RRE) reveals a conserved RNA motif required for high affinity Rev binding in both HIV-1 and EIAV

A cis-acting RNA regulatory element, the Rev-responsive element (RRE), has essential roles in replication of lentiviruses, including human immunodeficiency virus (HIV-1) and equine infection anemia virus (EIAV). The RRE binds the viral trans-acting regulatory protein, Rev, to mediate nucleocytoplasmic transport of incompletely spliced mRNAs encoding viral structural genes and genomic RNA. Because of its potential as a clinical target, RRE-Rev interactions have been well studied in HIV-1; however, detailed molecular structures of Rev-RRE complexes in other lentiviruses are still lacking. In this study, we investigate the secondary structure of the EIAV RRE and interrogate regulatory protein-RNA interactions in EIAV Rev-RRE complexes. Computational prediction and detailed chemical probing and footprinting experiments were used to determine the RNA secondary structure of EIAV RRE-1, a 555 nt region that provides RRE function in vivo. Chemical probing experiments confirmed the presence of several predicted loop and stem-loop structures, which are conserved among 140 EIAV sequence variants. Footprinting experiments revealed that Rev binding induces significant structural rearrangement in two conserved domains characterized by stable stem-loop structures. Rev binding region-1 (RBR-1) corresponds to a genetically-defined Rev binding region that overlaps exon 1 of the EIAV rev gene and contains an exonic splicing enhancer (ESE). RBR-2, characterized for the first time in this study, is required for high affinity binding of EIAV Rev to the RRE. RBR-2 contains an RNA structural motif that is also found within the high affinity Rev binding site in HIV-1 (stem-loop IIB), and within or near mapped RRE regions of four additional lentiviruses. The powerful integration of computational and experimental approaches in this study has generated a validated RNA secondary structure for the EIAV RRE and provided provocative evidence that high affinity Rev binding sites of HIV-1 and EIAV share a conserved RNA structural motif. The presence of this motif in phylogenetically divergent lentiviruses suggests that it may play a role in highly conserved interactions that could be targeted in novel anti-lentiviral therapies.     

Stereospecificity of short Rev-derived peptide interactions with RRE IIB RNA

The essential HIV-1 regulatory protein Rev binds to the Rev responsive element (RRE) of the HIV-1 mRNA. A short alpha-helical peptide derived from Rev (Rev 34-50) and a truncated form of the RRE sequence (RRE IIB) provide a useful in vitro system to study the interactions between Rev and RRE. The current studies focus on evaluating the specificity of the binding interactions between Rev 34-50 and RRE IIB. The binding of L- and D-Rev peptides to natural and enantiomeric RRE IIB RNA was studied by fluorescence spectroscopy. D-Rev and L-Rev peptides bind to RRE IIB with similar affinities. CD measurements are consistent with a nonhelical, probably beta-hairpin, conformation for D-Rev in the complex. The binding affinities of D/L Rev peptides to L-RRE IIB RNA are also similar to those with natural D-RRE IIB. Furthermore, the conformations of L- and D-peptides when bound to L-RRE are reciprocal to the conformations of these peptides in complex with D-RRE. RNA footprinting studies show that L- and D-Rev peptides bind to the same site on RRE IIB. Our results demonstrate lack of stereospecificity in RRE RNA-Rev peptide interactions. However, it is quite possible that the interactions between full-length Rev protein and RRE are highly specific.     

Multiple copies of the Mason-Pfizer monkey virus constitutive RNA transport element lead to enhanced HIV-1 Gag expression in a context-dependent manner

Retroviral gene expression requires nuclear export and translation of incompletely spliced RNA. In the case of human immunodeficiency virus (HIV), this is facilitated by the viral Rev protein binding to its cognate RNA response element (RRE), while other retroviruses contain constitutive transport elements (CTE) binding to cellular factors. These CTE can substitute for the HIV-1 Rev/RRE system, albeit with reduced efficiency. Here, we show that multimeric copies of the CTE restore HIV-1 protein expression to levels comparable to or higher than Rev/RRE in various cell lines from different species. We suggest that multimerization of export factors is important for CTE function, as reported for Rev. CTE function was not affected when the element was displaced from its natural position close to the poly(A) signal, while insertion of an intron into the 3′-untranslated region (3′-UTR) severely reduced CTE activity. In this case, cytoplasmic RNA degradation was observed, which may be mediated by nonsense-mediated RNA decay. In contrast, Rev-dependent gene expression was insensitive to an intron in the 3′-UTR. Finally, we show that the putative CTE-binding protein RNA helicase A is not specifically translocated into the cytoplasm upon overexpression of CTE-containing RNA.     

Rev proteins of human and simian immunodeficiency virus enhance RNA encapsidation

The main function attributed to the Rev proteins of immunodeficiency viruses is the shuttling of viral RNAs containing the Rev responsive element (RRE) via the CRM-1 export pathway from the nucleus to the cytoplasm. This restricts expression of structural proteins to the late phase of the lentiviral replication cycle. Using Rev-independent gag-pol expression plasmids of HIV-1 and simian immunodeficiency virus and lentiviral vector constructs, we have observed that HIV-1 and simian immunodeficiency virus Rev enhanced RNA encapsidation 20- to 70-fold, correlating well with the effect of Rev on vector titers. In contrast, cytoplasmic vector RNA levels were only marginally affected by Rev. Binding of Rev to the RRE or to a heterologous RNA element was required for Rev-mediated enhancement of RNA encapsidation. In addition to specific interactions of nucleocapsid with the packaging signal at the 5' end of the genome, the Rev/RRE system provides a second mechanism contributing to preferential encapsidation of genomic lentiviral RNA.     

An anti-apoptotic protein, Hax-1, inhibits the HIV-1 rev function by altering its sub-cellular localization

The human immunodeficiency virus type 1 (HIV-1) Rev protein facilitates the nuclear export of viral mRNA containing the Rev response element (RRE). Although several host proteins co-operating with Rev in viral RNA export have been reported, little is known about the innate host defense factors that Rev overcomes to mediate the nuclear export of unspliced viral mRNAs. We report here that an anti-apoptotic protein, HS1-associated protein X-1 (Hax-1), a target of HIV-1 Vpr, interacts with Rev and inhibits its activity in RRE-mediated gene expression. Co-expression of Sam68 emancipates Rev activity from Hax-1-mediated inhibition. Hax-1 does not bind to RRE RNA by itself, but inhibits Rev from binding to RRE RNA in vitro. The impact of Hax-1 on Rev/RRE interactions in vitro correlates well with the reduced level of RRE-containing mRNA in vivo. Immunofluorescence studies further reveal that Hax-1 and Rev are cytoplasmic and nuclear proteins, respectively, when expressed independently. However, in Hax-1 co-expressing cells, Rev is translocated from the nucleus to the cytoplasm, where it is co-localized with Hax-1 in the cytoplasm. We propose that over-expression of Hax-1, possibly through binding to Rev, may interfere with the stability/export of RRE-containing mRNA and target the RNA for degradation.     

Functional Analysis of the Human Immunodeficiency Virus Type 1 Rev Protein Oligomerization Interface

The expression of human immunodeficiency virus type 1 (HIV-1) structural proteins requires the action of the viral trans-regulatory protein Rev. Rev is a nuclear shuttle protein that directly binds to its cis-acting Rev response element (RRE) RNA target sequence. Subsequent oligomerization of Rev monomers on the RRE and interaction of Rev with a cellular cofactor(s) result in the cytoplasmic accumulation of RRE-containing viral mRNAs. Moreover, Rev by itself is exported from the nucleus to the cytoplasm. Although it has been demonstrated that Rev multimerization is critically required for Rev activity and hence for HIV-1 replication, the number of Rev monomers required to form a trans-activation-competent complex on the RRE is unknown. Here we report a systematic analysis of the putative multimerization domains within the Rev trans-activator protein. We identify the amino acid residues which are part of the proposed single hydrophobic surface patch in the Rev amino terminus that mediates intermolecular interactions. Furthermore, we show that the expression of a multimerization-deficient Rev mutant blocks HIV-1 replication in a trans-dominant (dominant-negative) fashion.     

Cooperative dimerization of a stably folded protein directed by a flexible RNA in the assembly of the HIV Rev dimer–RRE stem II complex

The binding of the HIV‐1 Rev protein as an oligomer to a viral RNA element, the Rev‐response element (RRE), mediates nuclear export of genomic RNA. Assembly of the Rev–RRE ribonucleoprotein (RNP) complex is nucleated by the binding of the first Rev molecule to stem IIB of the RRE. This is followed by stepwise addition of a total of ~six Rev molecules along the RRE through a combination of RNA–protein and protein–protein interactions. RRE stem II, which forms a three‐way junction consisting of stems IIA, IIB and IIC, has been shown to bind to two Rev molecules in a cooperative manner, with the second Rev molecule binding to the junction region of stem II. The results of base substitutions at the stem II junction, and characterization of stem II junction variants selected from a randomized library showed that an “open” flexible structure is preferred for binding of the second Rev molecule, and that binding of the second Rev molecule to the junction region is not sequence‐specific. Alanine substitutions of a number of Rev amino acid residues implicated to be important for Rev folding in previous structural studies were found to result in a dramatic decrease in the binding of the second Rev molecule. These results support the model that proper folding of Rev is critical in ensuring that the flexible RRE is able to correctly position Rev molecules for specific RNP assembly, and suggests that targeting Rev folding may be effective in the inhibition of Rev function. Copyright © 2015 John Wiley & Sons, Ltd.     

An Intrabody Based on a Llama Single-domain Antibody Targeting the N-terminal α-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 α-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.     

Function of the human immunodeficiency virus types 1 and 2 Rev proteins is dependent on their ability to interact with a structured region present in env gene mRNA.

The interaction of the human immunodeficiency virus type 1 (HIV-1) Rev protein with a structured region in env mRNA (the Rev-responsive element [RRE]) mediates the export of structural mRNAs from the nucleus to the cytoplasm. We demonstrated that unlike HIV-1 Rev, which functions with both the HIV-1 and HIV-2 RREs, HIV-2 Rev functions only with the HIV-2 RRE. Rev-RRE binding studies suggested that the lack of nonreciprocal complementation stems from the inability of HIV-2 Rev to interact with HIV-1 RRE RNA. Maintenance of RNA secondary structure, rather than the primary nucleotide sequence, appeared to be the major determinant for interaction of both HIV-1 and HIV-2 Rev with the HIV-2 RRE. Moreover, the binding domain of the HIV-2 RRE recognized by HIV-1 Rev was dissimilar to the binding domain of the HIV-1 RRE, in terms of both secondary structure and primary nucleotide sequence. Our results support the hypothesis that function of HIV Rev proteins and possibly the functionally similar Rex proteins encoded by the human T-cell leukemia viruses (HTLVs) HTLV-I and HTLV-II is controlled by the presence of RNA secondary structure generated within the RRE RNA.     

HIV-1 structural gene expression requires the binding of multiple Rev monomers to the viral RRE: implications for HIV-1 latency

Expression of the structural proteins of HIV-1 requires the direct interaction of the viral Rev trans-activator with its cis-acting RNA target sequence, the Rev response element or RRE. Here, we demonstrate that this specific RNA-binding event is, as expected, mediated by the conserved arginine-rich motif of Rev. However, we also show that amino acid residues located proximal to this basic domain that are critical for in vivo Rev function are dispensable for sequence-specific binding to the RRE. Instead, these sequences are required for the multimerization of Rev on the viral RRE target sequence. The observation that Rev function requires the sequential binding of multiple Rev molecules to the RRE provides a biochemical explanation for the observed threshold effect for Rev function in vivo and suggests a molecular model for the high incidence of latent infection by HIV-1.     

Specific regulation of mRNA splicing in vitro by a peptide from HIV-1 Rev

The Rev protein of HIV-1 regulates the synthesis of partially spliced forms of cytoplasmic viral mRNA by binding to a cis-acting RNA sequence, the Rev response element (RRE). We have investigated the regulation of splicing in vitro and have shown that Rev specifically inhibits splicing of pre-mRNAs containing an RRE by 3- to 4-fold. A synthetic peptide of 17 amino acids containing the RNA-binding domain of Rev is highly functional and specifically inhibits splicing by up to 30-fold. Other peptides that bind to the RRE with high affinity, but with low specificity, do not specifically inhibit splicing. Six repeated monomeric binding sites for the peptide can substitute for the RRE, indicating that regulation by Rev requires interactions with multiple sites. The peptide acts at a step in the assembly of splicing complexes, suggesting that one of the functions of the basic region of Rev is to prevent formation of a functional spliceosome.     

Cross-activation of the Rex proteins of HTLV-I and BLV and of the Rev protein of HIV-1 and nonreciprocal interactions with their RNA responsive elements

The Rex regulatory proteins of human T-cell leukemia virus type I (HTLV-I) and bovine leukemia virus (BLV), and the Rev protein of human immunodeficiency virus type 1 (HIV-1), promote the cytoplasmic accumulation and translation of viral messenger mRNAs encoding structural proteins. Rev and Rex act through cis-acting elements on the viral RNA; these elements are named Rev- and Rex-responsive elements, or RRE and RXRE, respectively. We show that the Rex proteins of HTLV-I and BLV are interchangeable, but only the Rex protein of HTLV-I can substitute for Rev of HIV-1. Rex of HTLV-I and Rev of HIV-1 appear to act on RRE by similar mechanisms. Rev of HIV-1 does not act on the RXRE of HTLV-I or BLV. The nonreciprocal action of Rev and Rex suggests that these factors interact directly with the cis-acting RNA elements of the two viruses.     

Comparative analysis of Rev function in human immunodeficiency virus types 1 and 2.

The Rev proteins of the related but distinct human immunodeficiency virus types 1 and 2 (HIV-1 and HIV-2) display incomplete functional reciprocity. One possible explanation for this observation is that HIV-2 Rev is unable to interact with the HIV-1 Rev-response element (RRE1). However, an analysis of the biological activity of chimeric proteins derived from HIV-1 and HIV-2 Rev reveals that this target specificity does not map to the Rev RNA binding domain but is instead primarily determined by sequences known to mediate Rev multimerization. Both HIV-1 and HIV-2 Rev are shown to bind the RRE1 in vitro with identical RNA sequence specificity. The observation that HIV-2 Rev can inhibit RRE1-dependent HIV-1 Rev function in trans indicates that the direct interaction of HIV-2 Rev with the RRE1 also occurs in vivo. These data suggest that HIV-2 Rev forms a protein-RNA complex with the RRE1 that leads to only minimal Rev activity. It is hypothesized that this low level of Rev function results from the incomplete and/or aberrant multimerization of HIV-2 Rev on this heterologous RNA target sequence.     

Fluorescence-based methods for evaluating the RNA affinity and specificity of HIV-1 Rev-RRE inhibitors

RNA plays a pivotal role in the replication of all organisms, including viral and bacterial pathogens. The development of small molecules that selectively interfere with undesired RNA activity is a promising new direction for drug design. Currently, there are no anti-HIV treatments that target nucleic acids. This article presents the HIV-1 Rev response element (RRE) as an important focus for the development of antiviral agents that target RNA. The Rev binding site on the RRE is highly conserved, even between different groups of HIV-1 isolates. Compounds that inhibit HIV replication by binding to the RRE and displacing Rev are therefore expected to retain activity across groups of genetically diverse HIV infections. Systematic evaluations of both the RRE affinity and specificity of numerous small molecule inhibitors are essential for deciphering the parameters that govern effective RRE recognition. This article discusses fluorescence-based techniques that are useful for probing a small molecule's RRE affinity and its ability to inhibit Rev-RRE binding. Rev displacement experiments can be conducted by observing the fluorescence anisotropy of a fluorescein-labeled Rev peptide, or by quantifying its displacement from a solid-phase immobilized RRE. Experiments conducted in the presence of competing nucleic acids are useful for evaluating the RRE specificity of Rev-RRE inhibitors. The discovery and characterization of new RRE ligands are described. Eilatin is a polycyclic aromatic heterocycle that has at least one binding site on the RRE (apparent Kd is approximately 0.13 microM), but it does not displace Rev upon binding the RRE (IC50 > 3 microM). In contrast, ethidium bromide and two eilatin-containing metal complexes show better consistency between their RRE affinity and their ability to displace a fluorescent Rev peptide from the RRE. These results highlight the importance of conducting orthogonal binding assays that establish both the RNA affinity of a small molecule and its ability to inhibit the function of the RNA target. Some Rev-RRE inhibitors, including ethidium bromide, Lambda-[Ru(bpy)(2)eilatin]2+, and Delta-[Ru(bpy)(2)eilatin]2+ also inhibit HIV-1 gene expression in cell cultures (IC50 = 0.2-3 microM). These (and similar) results should facilitate the future discovery and implementation of anti-HIV drugs that are targeted to viral RNA sites. In addition, a deeper general understanding of RNA-small molecule recognition will assist in the effective targeting of other therapeutically important RNA sites.     

Dynamics of RNA-protein interactions in the HIV-1 Rev-RRE complex visualized by 6-thioguanosine-mediated photocrosslinking.

Expression of the structural proteins of human immunodeficiency virus type 1 (HIV-1) requires the direct interaction of multiple copies of the viral protein Rev with its target RNA, the Rev response element (RRE). RRE is a complex 351-nt RNA that is highly structured and located within the viral env gene. During initial Rev-RRE recognition, Rev binds with high affinity to a bubble structure located within the RRE RNA stem-loop II. We have used a site-specific photocrosslinking method based on 6-thioguanosine (6-thioG) photochemistry to probe the conformation of the high-affinity binding site of RRE RNA and its interactions with Rev protein under physiological conditions. A minimal duplex RNA containing the bubble region of RRE and 12 flanking base pairs was synthesized chemically. Two different RRE constructs with a single photoactive nucleoside (6-thio-dG or 6-thioG) at position 47 or 48 were synthesized. Upon UV irradiation, 6-thioG at both positions formed interstrand covalent crosslinks in RRE RNA. Mapping of crosslink sites by RNA sequencing revealed that 6-thioG at position 47 or 48 crosslinked to A73. In the presence of Rev, both RNA-RNA and RNA-protein crosslinks were observed, however, the RNA-RNA crosslink site was unchanged. Our results provide direct evidence that, during RNA-protein recognition, Rev is in close proximity to O6 of G47 and G48 in the major groove of RRE RNA. Our results also show that the bubble region of RRE RNA has a biologically relevant structure where G47 and G48 are in close proximity to A73 and this RNA structure is not changed significantly upon Rev binding. We propose that Rev protein recognizes and binds to specific structural elements of RRE RNA containing non-Watson-Crick base pairs and such structures could be a determinant for recognition by other RNA-binding proteins. Our site-specific crosslinking methods provide a general approach to capture dynamic states of biologically relevant RNA structures that are otherwise missed by NMR and X-ray crystallographic studies.     

HIV-1 structural gene expression requires binding of the Rev trans-activator to its RNA target sequence

Expression of human immunodeficiency virus type 1 structural proteins requires both the viral Rev trans-activator and its cis-acting RNA target sequence, the Rev response element (RRE). The RRE has been mapped to a conserved region of the HIV-1 env gene and is predicted to form a complex, highly stable RNA stem-loop structure. Site-directed mutagenesis was used to define a small subdomain of the RRE, termed stem-loop II, that is essential for biological activity. Gel retardation assays demonstrated that the Rev trans-activator is a sequence-specific RNA binding protein. The RRE stem-loop II subdomain was found to be both necessary and sufficient for the binding of Rev by the RRE. We propose that the HIV-1 Rev trans-activator belongs to a new class of sequence-specific RNA binding proteins characterized by the presence of an arginine-rich binding motif.     

Molecular recognition of a branched peptide with HIV-1 Rev Response Element (RRE) RNA

Interaction of HIV-1 rev response element (RRE) RNA with its cognate protein, Rev, is critical for HIV-1 replication. Understanding the mode of interaction between RRE RNA and ligands at the binding site can facilitate RNA molecular recognition as well as provide a strategy for developing anti-HIV therapeutics. Our approach utilizes branched peptides as a scaffold for multivalent binding to RRE IIB (high affinity rev binding site) with incorporation of unnatural amino acids to increase affinity via non-canonical interactions with the RNA. Previous high throughput screening of a 46,656-member library revealed several hits that bound RRE IIB RNA in the sub-micromolar range. In particular, the lead compound, 4B3, displayed a K_d value of 410?nM and demonstrated selectivity towards RRE. A ribonuclease protection assay revealed that 4B3 binds to the stem-loop structure of RRE IIB RNA, which was confirmed by SHAPE analysis with 234 nt long NL4-3 RRE RNA. Our studies further indicated interaction of 4B3 with both primary and secondary Rev binding sites.