Extensive sequence-specific information throughout the CAR/RRE, the target sequence of the human immunodeficiency virus type 1 Rev protein

Sequence and Functional Variation in the HIV-1 Rev Regulatory Axis

BACKGROUND

To complete its replication cycle, HIV-1 requires the nucleocytoplasmic export of intron-containing viral mRNAs. This process is ordinarily restricted by the cell, but HIV overcomes the block by means of a viral protein, Rev, and an RNA secondary structure found in all unspliced and incompletely spliced viral mRNAs called the Rev Response Element (RRE). In vivo activity of the Rev-RRE axis requires Rev binding to the RRE, oligomerization of Rev to form a competent ribonucleoprotein complex, and recruitment of cellular factors including Crm1 and RanGTP in order to export the targeted transcript. Sequence variability is observed among primary isolates in both Rev and the RRE, and the activity of both can be modulated through relatively small sequence changes. Primary isolates show differences in Rev-RRE activity and a few studies have found a correlation between lower Rev-RRE activity and slower progression of clinical disease. Lower Rev-RRE activity has also been associated with the evasion of cytotoxic T lymphocyte mediated killing.

CONCLUSION

The HIV-1 Rev-RRE regulatory axis is an understudied mechanism by which viral adaptation to diverse immune milieus may take place. There is evidence that this adaptation plays a role in HIV pathogenesis, particularly in immune evasion and latency, but further studies with larger sample sizes are warranted.

Optimization and Performance Analysis of a Massively Parallel Dynamic Programming Algorithm for Rna Secondary Structure Prediction

An optimized and parallelized form of a dynamic pro gramming algorithm capable of generating optimal and suboptimal RNA secondary structures is pre sented. Implementation of this algorithm on a MasPar MP-2 with 16K processors is shown to perform ex tremely well for very large nucleic acid sequences such as HIV (AIDS) and Rhinovirus (common cold). These sequences are, respectively, 9,128 and 7,208 nu cleotides in length. By taking advantage of the parallel nature of MasPar and also optimizing the communica tion requirements the implementation essentially re duced the algorithm from order O(n3) to 0(n2). This reduction in complexity enables us to fold large RNA sequences in reasonable amounts of time. This capa bility has proven to be a valuable tool in studying the molecular structure and biological function of mole cules this large.

The HIV-1 Rev response element (RRE) adopts alternative conformations that promote different rates of virus replication

The HIV Rev protein forms a complex with a 351 nucleotide sequence present in unspliced and incompletely spliced human immunodeficiency virus (HIV) mRNAs, the Rev response element (RRE), to recruit the cellular nuclear export receptor Crm1 and Ran-GTP. This complex facilitates nucleo-cytoplasmic export of these mRNAs. The precise secondary structure of the HIV-1 RRE has been controversial, since studies have reported alternative structures comprising either four or five stem-loops. The published structures differ only in regions that lie outside of the primary Rev binding site. Using in-gel SHAPE, we have now determined that the wt NL4-3 RRE exists as a mixture of both structures. To assess functional differences between these RRE ‘conformers’, we created conformationally locked mutants by site-directed mutagenesis. Using subgenomic reporters, as well as HIV replication assays, we demonstrate that the five stem-loop form of the RRE promotes greater functional Rev/RRE activity compared to the four stem-loop counterpart.

Mutational robustness accelerates the origin of novel RNA phenotypes through phenotypic plasticity

Novel phenotypes can originate either through mutations in existing genotypes or through phenotypic plasticity, the ability of one genotype to form multiple phenotypes. From molecules to organisms, plasticity is a ubiquitous feature of life, and a potential source of exaptations, adaptive traits that originated for nonadaptive reasons. Another ubiquitous feature is robustness to mutations, although it is unknown whether such robustness helps or hinders the origin of new phenotypes through plasticity. RNA is ideal to address this question, because it shows extensive plasticity in its secondary structure phenotypes, a consequence of their continual folding and unfolding, and these phenotypes have important biological functions. Moreover, RNA is to some extent robust to mutations. This robustness structures RNA genotype space into myriad connected networks of genotypes with the same phenotype, and it influences the dynamics of evolving populations on a genotype network. In this study I show that both effects help accelerate the exploration of novel phenotypes through plasticity. My observations are based on many RNA molecules sampled at random from RNA sequence space, and on 30 biological RNA molecules. They are thus not only a generic feature of RNA sequence space but are relevant for the molecular evolution of biological RNA.

Functional analyses reveal extensive RRE plasticity in primary HIV-1 sequences selected under selective pressure

BACKGROUND

HIV-1 Rev response element (RRE) is a functional region of viral RNA lying immediately downstream to the junction of gp120 and gp41 in the env coding sequence. The RRE is essential for HIV replication and binds with the Rev protein to facilitate the export of viral mRNA from nucleus to cytoplasm. It has been suggested that changes in the predicted secondary structure of primary RRE sequences impact the function of the RREs; however, functional assays have not yet been performed. The aim of this study was to characterize the genetic, structural and functional variation in the RRE primary sequences selected in vivo by Enfuvirtide pressure.

RESULTS

Multiple RRE variants were obtained from viruses isolated from patients who failed an Enfuvirtide-containing regimen. Different alterations were observed in the predicted RRE secondary structures, with the abrogation of the primary Rev binding site in one of the variants. In spite of this, most of the RRE variants were able to bind Rev and promote the cytoplasmic export of the viral mRNAs with equivalent efficiency in a cell-based assay. Only RRE45 and RRE40-45 showed an impaired ability to bind Rev in a gel-shift binding assay. Unexpectedly, this impairment was not reflected in functional capacity when RNA export was evaluated using a reporter assay, or during virus replication in lymphoid cells, suggesting that in vivo the RRE would be highly malleable.

CONCLUSIONS

The Rev-RRE functionality is unaffected in RRE variants selected in patients failing an ENF-containing regimen. Our data show that the current understanding of the Rev-RRE complex structure does not suffice and fails to rationally predict the function of naturally occurring RRE mutants. Therefore, this data should be taken into account in the development of antiviral agents that target the RRE-Rev complex.

Evolutionary patterns of non-coding RNAs

A plethora of new functions of non-coding RNAs (ncRNAs) have been discovered in past few years. In fact, RNA is emerging as the central player in cellular regulation, taking on active roles in multiple regulatory layers from transcription, RNA maturation, and RNA modification to translational regulation. Nevertheless, very little is known about the evolution of this "Modern RNA World" and its components. In this contribution, we attempt to provide at least a cursory overview of the diversity of ncRNAs and functional RNA motifs in non-translated regions of regular messenger RNAs (mRNAs) with an emphasis on evolutionary questions. This survey is complemented by an in-depth analysis of examples from different classes of RNAs focusing mostly on their evolution in the vertebrate lineage. We present a survey of Y RNA genes in vertebrates and study the molecular evolution of the U7 snRNA, the snoRNAs E1/U17, E2, and E3, the Y RNA family, the let-7 microRNA (miRNA) family, and the mRNA-like evf-1 gene. We furthermore discuss the statistical distribution of miRNAs in metazoans, which suggests an explosive increase in the miRNA repertoire in vertebrates. The analysis of the transcription of ncRNAs suggests that small RNAs in general are genetically mobile in the sense that their association with a hostgene (e.g. when transcribed from introns of a mRNA) can change on evolutionary time scales. The let-7 family demonstrates, that even the mode of transcription (as intron or as exon) can change among paralogous ncRNA.

Single-nucleotide changes in the HIV Rev-response element mediate resistance to compounds that inhibit Rev function

Previously we described the identification of two compounds (3-amino-5-ethyl-4,6-dimethylthieno[2,3-b]pyridine-2-carboxamide [103833] and 4-amino-6-methoxy-2-(trifluoromethyl)-3-quinolinecarbonitrile [104366]) that interfered with HIV replication through the inhibition of Rev function. We now describe resistant viral variants that arose after drug selection, using virus derived from two different HIV proviral clones, NL4-3 and R7/3. With HIV(NL4-3), each compound selected a different single point mutation in the Rev response element (RRE) at the bottom of stem-loop IIC. Either mutation led to the lengthening of the stem-loop IIC stem by an additional base pair, creating an RRE that was more responsive to lower concentrations of Rev than the wild type. Surprisingly, wild-type HIV(R7/3) was also found to be inhibited when tested with these compounds, in spite of the fact this virus already has an RNA stem-loop IIC similar to the one in the resistant NL4-3 variant. When drug resistance was selected in HIV(R7/3), a virus arose with two nucleotide changes that mapped to the envelope region outside the RRE. One of these nucleotide changes was synonymous with respect to env, and one was not. The combination of both nucleotide changes appeared to be necessary for the resistance phenotype as the individual point mutations by themselves did not convey resistance. Thus, although drug-resistant variants can be generated with both viral strains, the underlying mechanism is clearly different. These results highlight that minor nucleotide changes in HIV RNA, outside the primary Rev binding site, can significantly alter the efficiency of the Rev/RRE pathway.

Structure of the HIV-1 Rev response element alone and in complex with regulator of virion (Rev) studied by atomic force microscopy

The interaction of multiple HIV-1 regulator of virion (Rev) proteins with the viral RNA target, the Rev response element (RRE), is critical for nuclear export of incompletely spliced and unspliced viral RNA, and for the onset of the late phase in the viral replication cycle. The heterogeneity of the Rev-RRE complex has made it difficult to study using conventional structural methods. In the present study, atomic force microscopy is applied to directly visualize the tertiary structure of the RRE RNA alone and in complex with Rev proteins. The appearance of the RRE is compatible with the earlier proposed RRE secondary structure in dimensions and overall shape, including a stalk and a head interpreted as stem I, and stem-loops II-V in the secondary structure model, respectively. Atomic force microscopy imaging of the Rev-RRE complex revealed an increased height of the structure both in the stalk and head regions, which is in accordance with a binding model in which Rev binding to a high affinity site in stem IIB triggers oligomerization of Rev proteins through cooperative binding along stem I in RRE. The present study demonstrates that atomic force microscopy comprises a useful technique to study complex biological structures of nucleic acids at high resolution.

Neutral network sizes of biological RNA molecules can be computed and are not atypically small

Background

Neutral networks or sets consist of all genotypes with a given phenotype. The size and structure of these sets has a strong influence on a biological system's robustness to mutations, and on its evolvability, the ability to produce phenotypic variation; in the few studied cases of molecular phenotypes, the larger this set, the greater both robustness and evolvability of phenotypes. Unfortunately, any one neutral set contains generally only a tiny fraction of genotype space. Thus, current methods cannot measure neutral set sizes accurately, except in the smallest genotype spaces.

Results

Here we introduce a generalized Monte Carlo approach that can measure neutral set sizes in larger spaces. We apply our method to the genotype-to-phenotype mapping of RNA molecules, and show that it can reliably measure neutral set sizes for molecules up to 100 bases. We also study neutral set sizes of RNA structures in a publicly available database of functional, noncoding RNAs up to a length of 50 bases. We find that these neutral sets are larger than the neutral sets in 99.99% of random phenotypes. Software to estimate neutral network sizes is available at .

Conclusion

The biological RNA structures we examined are more abundant than random structures. This indicates that their robustness and their ability to produce new phenotypic variants may also be high.

Resistance to RevM10 inhibition reflects a conformational switch in the HIV-1 Rev response element

Nuclear export of certain HIV-1 mRNAs requires an interaction between the viral Rev protein and the Rev response element (RRE), a structured element located in the Env region of its RNA genome. This interaction is an attractive target for both drug design and gene therapy, exemplified by RevM10, a transdominant negative protein that, when introduced into host cells, disrupts viral mRNA export. However, two silent G->A mutations in the RRE (RRE61) confer RevM10 resistance, which prompted us to examine RRE structure using a novel chemical probing strategy. Variations in region III/IV/V of mutant RNAs suggest a stepwise rearrangement to RevM10 resistance. Mass spectrometry was used to directly assess Rev "loading" onto RRE and its variants, indicating that this is unaffected by RNA structural changes. Similarity in chemical footprints with mutant protein implicates additional host factors in RevM10 resistance.

Robustness and evolvability: a paradox resolved

Understanding the relationship between robustness and evolvability is key to understand how living things can withstand mutations, while producing ample variation that leads to evolutionary innovations. Mutational robustness and evolvability, a system's ability to produce heritable variation, harbour a paradoxical tension. On one hand, high robustness implies low production of heritable phenotypic variation. On the other hand, both experimental and computational analyses of neutral networks indicate that robustness enhances evolvability. I here resolve this tension using RNA genotypes and their secondary structure phenotypes as a study system. To resolve the tension, one must distinguish between robustness of a genotype and a phenotype. I confirm that genotype (sequence) robustness and evolvability share an antagonistic relationship. In stark contrast, phenotype (structure) robustness promotes structure evolvability. A consequence is that finite populations of sequences with a robust phenotype can access large amounts of phenotypic variation while spreading through a neutral network. Population-level processes and phenotypes rather than individual sequences are key to understand the relationship between robustness and evolvability. My observations may apply to other genetic systems where many connected genotypes produce the same phenotypes.

Comparative analysis of structured RNAs in S. cerevisiae indicates a multitude of different functions

Background

Non-coding RNAs (ncRNAs) are an emerging focus for both computational analysis and experimental research, resulting in a growing number of novel, non-protein coding transcripts with often unknown functions. Whole genome screens in higher eukaryotes, for example, provided evidence for a surprisingly large number of ncRNAs. To supplement these searches, we performed a computational analysis of seven yeast species and searched for new ncRNAs and RNA motifs.

Results

A comparative analysis of the genomes of seven yeast species yielded roughly 2800 genomic loci that showed the hallmarks of evolutionary conserved RNA secondary structures. A total of 74% of these regions overlapped with annotated non-coding or coding genes in yeast. Coding sequences that carry predicted structured RNA elements belong to a limited number of groups with common functions, suggesting that these RNA elements are involved in post-transcriptional regulation and/or cellular localization. About 700 conserved RNA structures were found outside annotated coding sequences and known ncRNA genes. Many of these predicted elements overlapped with UTR regions of particular classes of protein coding genes. In addition, a number of RNA elements overlapped with previously characterized antisense transcripts. Transcription of about 120 predicted elements located in promoter regions and other, previously un-annotated, intergenic regions was supported by tiling array experiments, ESTs, or SAGE data.

Conclusion

Our computational predictions strongly suggest that yeasts harbor a substantial pool of several hundred novel ncRNAs. In addition, we describe a large number of RNA structures in coding sequences and also within antisense transcripts that were previously characterized using tiling arrays.

Derivation of primary sequences and secondary structures of rev responsive element from HIV-1 infected mothers and infants following vertical transmission

We have characterized the primary RRE sequences of HIV-1, including in vivo genetic variation and functional motifs required for Rev-RRE interactions as well as evaluated the RNA secondary structures of RRE derived from five mother-infant pairs following vertical transmission. Multiple (157) RRE sequences derived from mother-infant pairs showed that primary nucleotide sequences of RRE were highly conserved with a low degree of viral heterogeneity following vertical transmission. We found that the RRE sequences from mothers and infants folded and retained all the essential stem-loop formation required for Rev-RRE interactions. More importantly, a primary 9-nucleotide (5'-CACTATGGG-3') RRE sequence in the stem-loop B that is required for optimal Rev recognition and must be presented as a stem-bulge-stem structure was highly conserved in most of the sequences. The domains required for RRE-host protein interactions were also conserved in most of the RRE sequences. Taken together, the primary RRE sequences in the context of secondary structures were maintained and the Rev-RRE interaction domains were conserved following vertical transmission, which is consistent with a crucial role of RRE in HIV-1 pathogenesis.

Robustness, evolvability, and neutrality

Biological systems, from macromolecules to whole organisms, are robust if they continue to function, survive, or reproduce when faced with mutations, environmental change, and internal noise. I focus here on biological systems that are robust to mutations and ask whether such systems are more or less evolvable, in the sense that they can acquire novel properties. The more robust a system is, the more mutations in it are neutral, that is, without phenotypic effect. I argue here that such neutral change--and thus robustness--can be a key to future evolutionary innovation, if one accepts that neutrality is not an essential feature of a mutation. That is, a once neutral mutation may cause phenotypic effects in a changed environment or genetic background. I argue that most, if not all, neutral mutations are of this sort, and that the essentialist notion of neutrality should be abandoned. This perspective reconciles two opposing views on the forces dominating organismal evolution, natural selection and random drift: neutral mutations occur and are especially abundant in robust systems, but they do not remain neutral indefinitely, and eventually become visible to natural selection, where some of them lead to evolutionary innovations.

Heterogeneity of HIV-1 Rev response element

We compiled all the RRE sequences of HIV-1 in the HIV Sequence Database and analyzed for base variation frequency at each nucleotide position. Positions with high frequency of base alteration scattered throughout the region, but primary sequences of almost all bases in stem IIA, Rev-binding bubble, and most of the stem region of stem-loop III were highly conserved. Comparing to HXB2 secondary structure, basepair-disrupting mutations did not distribute evenly in every region of the RRE. Stem I, stem IIB outside the Rev-binding site, stem IIC, and proximal parts of stem IV and V were more variable, while stem IIA, stem III, and distal parts of stem IV and V were highly conserved. These data indicated that RREs are structurally heterogeneous. The uneven distribution of variation in both primary sequence and the stem structure put forward highly conserved sites that might be more crucial to the function of RRE than the less conserved parts.

Binding of equine infectious anemia virus rev to an exon splicing enhancer mediates alternative splicing and nuclear export of viral mRNAs

In addition to facilitating the nuclear export of incompletely spliced viral mRNAs, equine infectious anemia virus (EIAV) Rev regulates alternative splicing of the third exon of the tat/rev mRNA. In the presence of Rev, this exon of the bicistronic RNA is skipped in a fraction of the spliced mRNAs. In this report, the cis-acting requirements for exon 3 usage were correlated with sequences necessary for Rev binding and transport of incompletely spliced RNA. The presence of a purine-rich exon splicing enhancer (ESE) was required for exon 3 recognition, and the addition of Rev inhibited exon 3 splicing. Glutathione-S-transferase (GST)-Rev bound to probes containing the ESE, and mutation of GAA repeats to GCA within the ESE inhibited both exon 3 recognition in RNA splicing experiments and GST-Rev binding in vitro. These results suggest that Rev regulates alternative splicing by binding at or near the ESE to block SR protein-ESE interactions. A 57-nucleotide sequence containing the ESE was sufficient to mediate Rev-dependent nuclear export of incompletely spliced RNAs. Rev export activity was significantly inhibited by mutation of the ESE or by trans-complementation with SF2/ASF. These results indicate that the ESE functions as a Rev-responsive element and demonstrate that EIAV Rev mediates exon 3 exclusion through protein-RNA interactions required for efficient export of incompletely spliced viral RNAs.

Prediction of common secondary structures of RNAs: a genetic algorithm approach

In this study we apply a genetic algorithm to a set of RNA sequences to find common RNA secondary structures. Our method is a three-step procedure. At the first stage of the procedure for each sequence, a genetic algorithm is used to optimize the structures in a population to a certain degree of stability. In this step, the free energy of a structure is the fitness criterion for the algorithm. Next, for each structure, we define a measure of structural conservation with respect to those in other sequences. We use this measure in a genetic algorithm to improve the structural similarity among sequences for the structures in the population of a sequence. Finally, we select those structures satisfying certain conditions of structural stability and similarity as predicted common structures for a set of RNA sequences. We have obtained satisfactory results from a set of tRNA, 5S rRNA, rev response elements (RRE) of HIV-1 and RRE of HIV-2/SIV, respectively.

Prediction of RNA base pairing probabilities on massively parallel computers

We present an implementation of McCaskill's algorithm for computing the base pair probabilities of an RNA molecule for massively parallel message passing architectures. The program can be used to routinely fold RNA sequences of more than 10,000 nucleotides. Applications to complete viral genomes are discussed.

Selection and characterization of human immunodeficiency virus type 1 mutants that are resistant to inhibition by the transdominant negative RevM10 protein

Intracellular immunization with RevM10, a transdominant negative form of the Rev protein, efficiently inhibits human immunodeficiency virus (HIV) replication in vitro and gene therapy protocols that use this modality are currently being evaluated in human clinical trials. Development of resistance to this kind of therapy has not been previously reported. Here we show that RevM10-resistant HIV type 1 (HIV-1) variants can be selected by in vitro passage of HIV-1 in a T-lymphoblastoid cell line constitutively expressing RevM10. Unexpectedly, the selected variants showed changes in the Rev response element (RRE) but no changes in Rev. Replacement of the wild-type RRE with a mutated RRE resulted in a virus that showed increased resistance to RevM10. After repeated passages of the resistant variant in cells expressing RevM10, a virus with an additional mutation in the viral vpu gene was selected. Surprisingly, a virus containing only this vpu mutation also showed some resistance to inhibition by RevM10.

Real-time kinetics of HIV-1 Rev-Rev response element interactions. Definition of minimal binding sites on RNA and protein and stoichiometric analysis

The kinetics of interaction between the human immunodeficiency virus-1 Rev protein and its RNA target, Rev response element (RRE) RNA was determined in vitro using a biosensor technique. Our results showed that the primary Rev binding site is a core stem-loop RNA molecule of 30 nucleotides that bound Rev at a 1:1 ratio, whereas the 244-nucleotide full-length RRE bound four Rev monomers. At high Rev concentrations, additional binding of Rev to RRE was observed with ratios of more than 10:1. Because RRE mutants that lacked the core binding site and were inactive in vivo bound Rev nonspecifically at these concentrations, the real stoichiometric ratio of Rev-RRE is probably closer to 4:1. Binding affinity of Rev for RRE was approximately 10(-10) M, whereas the affinity for the core RNA was about 10(-11) M, the difference being due to the contribution of low affinity binding sites on the RRE. Mathematical analysis suggested cooperativity of Rev binding, probably mediated by the Rev oligomerization domains. C-terminal deletions of Rev had no effect on RRE binding, but truncation of the N terminus by as few as 11 residues significantly reduced binding specificity. This method was also useful to rapidly evaluate the potential of aminoglycoside antibiotics, to inhibit the Rev-RRE interaction.

Automatic detection of conserved base pairing patterns in RNA virus genomes

Almost all RNA molecules--and consequently also almost all subsequences of a large RNA molecule-form secondary structures. The presence of secondary structure in itself therefore does not indicate any functional significance. In fact, we cannot expect a conserved secondary structure for all parts of a viral genome or a mRNA, even if there is a significant level of sequence conservation. We present a novel method for detecting conserved RNA secondary structures in a family of related RNA sequences. The method is based on combining the prediction of base pair probability matrices and comparative sequence analysis. It can be applied to small sets of long sequences and does not require a prior knowledge of conserved sequence or structure motifs. As such it can be used to scan large amounts of sequence data for regions that warrant further experimental investigation. Applications to complete genomic RNAs of some viruses show that in all cases the known secondary structure features are identified. In addition, we predict a substantial number of conserved structural elements which have not been described so far.

Automatic detection of conserved RNA structure elements in complete RNA virus genomes

We propose a new method for detecting conserved RNA secondary structures in a family of related RNA sequences. Our method is based on a combination of thermodynamic structure prediction and phylogenetic comparison. In contrast to purely phylogenetic methods, our algorithm can be used for small data sets of approximately 10 sequences, efficiently exploiting the information contained in the sequence variability. The procedure constructs a prediction only for those parts of sequences that are consistent with a single conserved structure. Our implementation produces reasonable consensus structures without user interference. As an example we have analysed the complete HIV-1 and hepatitis C virus (HCV) genomes as well as the small segment of hantavirus. Our method confirms the known structures in HIV-1 and predicts previously unknown conserved RNA secondary structures in HCV.

The HIV-1 Rev protein

The nuclear export of intron-containing HIV-1 RNA is critically dependent on the activity of Rev, a virally encoded sequence-specific RNA-binding protein. Rev shuttles between the nucleus and the cytoplasm and harbors both a nuclear localization signal and a nuclear export signal. These essential peptide motifs have now been shown to function by accessing cellular signal-mediated pathways for nuclear import and nuclear export. HIV-1 Rev therefore represents an excellent system with which to study aspects of transport across the nuclear envelope.

HIV Rev-dependent binding of SF2/ASF to the Rev response element: possible role in Rev-mediated inhibition of HIV RNA splicing

Production of the structural and enzymatic proteins of type 1 human immunodeficiency virus (HIV-1) is controlled by the rev regulatory gene product. The 116-amino acid Rev protein acts by binding to the Rev response element (RRE), a complex RNA stem-loop structure located within the env gene of HIV. Rev exerts a series of posttranscriptional effects, including the inhibition of viral RNA splicing, the activation of nuclear export of incompletely spliced viral RNAs, and the enhancement of translation of RRE-containing RNAs. Our studies now demonstrate that at least one member of the SR family of splicing factors, SF2/ASF, specifically binds to a subregion of the RRE in vitro in a Rev-dependent manner. Furthermore, expression of high levels of SF2/ASF inhibits Rev function and impairs HIV replication in vivo. Both the in vitro binding of SF2/ASF to the Rev/RRE complex and the in vivo inhibition of Rev action by SF2/ASF are abrogated by mutation of the N-terminal RNA recognition motif but are not affected by mutation of the C-terminal arginine-serine-rich domain. These findings suggest that Rev inhibition of HIV splicing likely involves recruitment of the essential splicing factor SF2/ASF to the Rev/RRE complex. However, these inhibitory effects of Rev on viral RNA splicing are apparently overcome by augmenting the intracellular levels of SF2/ASF expression.

Two secondary structures for the RRE of HIV-1?

The RRE, the target sequence for the Rev protein of HIV-1, is a highly structured RNA sequence characterized by multiple stem loops. Although agreement on the stem/loop organization outside the high-affinity site was reached some time ago by several laboratories, recent work has suggested an alternative structure in which sequences from two of the stem/loops (IV and V) pair to form one long stem/loop (IV/V) when enough HIV material is present to allow the formation of an extended central stem structure (I/I'). Here we address the contribution of the original and alternative structures to function in RRE constructs with short and extended I'I' regions. We confirm that extended I/I' structures improve RRE function and may stabilize the overall structure. However, we find no evidence that an extended I/I' structure preferentially stabilizes either alternative structure with respect to the other. The two alternative structures are approximately functionally equivalent, and both are probably present in an in vivo population of RREs.

Inhibition of HIV-1 Rev-RRE interaction by diphenylfuran derivatives

The interactions between RNA structures, such as RRE in the HIV-1 genome, and proteins, such as Rev of HIV-1, are essential for efficient viral replication. Compounds that bind specifically to such RNAs and disrupt their protein complexes offer a novel mechanism for inhibition of replication of the virus. As a step in this approach, we have designed and characterized a series of synthetic diphenylfuran cations that selectively inhibit Rev binding to RRE. Fluorescence titrations and gel band-shift results indicate that the diphenylfurans bind to RRE and inhibit Rev complex formation in a structure-dependent manner. The derivative with the greatest affinity for RRE has an association constant of greater than 10(7) M-1 and inhibits formation of the Rev--RRE complex at concentrations below 1 microM. It binds to RRE considerably more strongly than it binds to simple RNA duplexes. Spectral changes and energy transfer results on complex formation suggest that the compound has a nonclassical intercalation binding mode. CD studies with modified RRE hairpins indicate that the active diphenylfurans bind at the structured internal loop of RRE and cause a conformational change. The most active diphenylfurans are tetracations that appear to bind to RRE by a threading intercalation mode and cause a conformational change in the RNA that is essential for inhibition of Rev complex formation with RRE.

Inhibition of HIV replication by sense and antisense rev response elements in HIV-based retroviral vectors

The life cycle of human immunodeficiency virus type 1 (HIV-1) is critically dependent on the transregulatory proteins Tat and Rev. Tat increases the production of HIV-specific mRNAs by direct binding to the transactivation response (TAR) element located at the 5' end of all HIV transcripts. In contrast, Rev uses a complex RNA stem loop structure, the Rev response element (RRE), which is found in full-length and singly spliced HIV transcripts. Rev is required for the cytoplasmic expression of full-length mRNAs encoding Gag, Pol, and Env structural proteins. The complex intracellular interactions between Tat, Rev, host cell factors, and their respective RNA response elements should be susceptible to interdiction by genetic therapies designed to introduce and express novel genetic information. We show that the expression of antisense RREs inhibited the cytoplasmic expression of RRE containing HIV-1 transcripts. HIV-based retroviral vectors containing either the antisense (-) or sense (+) RREs inhibited HIV replication in transient transfections. The production of full-length HIV mRNA was also decreased significantly by the expression of RREs in either orientation. Interestingly, there was a paradoxic increase in HIV p24 gag production at low levels of inhibitor; this effect may have been the result of encapsidation of RRE-containing HIV-based retroviral vectors. The data suggest that the introduction and inducible expression of RRE-containing, HIV-based retroviral vectors may have therapeutic value in HIV infection.

STRUCTURELAB: a heterogeneous bioinformatics system for RNA structure analysis

STRUCTURELAB is a computational system that has been developed to permit the use of a broad array of approaches for the analysis of the structure of RNA. The goal of the development is to provide a large set of tools that can be well integrated with experimental biology to aid in the process of the determination of the underlying structure of RNA sequences. The approach taken views the structure determination problem as one of dealing with a database of many computationally generated structures and provides the capability to analyze this data set from different perspectives. Many algorithms are integrated into one system that also utilizes a heterogeneous computing approach permitting the use of several computer architectures to help solve the posed problems. These different computational platforms make it relatively easy to incorporate currently existing programs as well as newly developed algorithms and to best match these algorithms to the appropriate hardware. The system has been written in Common Lisp running on SUN or SGI Unix workstations, and it utilizes a network of participating machines defined in reconfigurable tables. A window-based interface makes this heterogeneous environment as transparent to the user as possible.

cis-acting elements in human immunodeficiency virus type 1 RNAs direct viral transcripts to distinct intranuclear locations

Two distinct intranuclear locations were identified for alternatively spliced RNA transcripts expressed from the pNL4-3 infectious molecular clone of human immunodeficiency virus (HIV) type 1. Multiply spliced HIV RNA encoding tat was detected within the nucleus in large clusters; immunostaining and colocalization studies using laser-scanning confocal microscopy revealed that these structures contained the non-small nuclear ribonucleoprotein RNA processing factor, SC35. In contrast, unspliced gag RNA was detected in much smaller granules distributed throughout the nucleus, with little or no association with SC35-containing granules. Analyses of nuclear RNA expressed from recombinant plasmids encoding gag (pCMVgag-2) alone or tat (pCMVtat-2) alone revealed distributions corresponding to those obtained with pNL4-3, indicating that expression within the context of the HIV provirus was not required for the distinct RNA locations detected for these transcripts. The presence of unspliced gag RNA in small granules was confirmed in infections of H9 T-lymphocytic cells, indicating that gag localization was not restricted to transient expression systems. The intranuclear distribution of gag RNA was dependent on specific RNA sequences. Deletion of a portion of the gag gene of pCMVgag-2, containing a cis-repressing inhibitory region, resulted in redirection of unspliced gag RNA from small granules into large SC35-containing clusters. The addition of the Rev-responsive element, RRE, to the deleted pCMVgag-2 construct resulted in RNA transcripts which were no longer associated with SC35. We also identified a cellular intron, rabbit beta-globin-intervening sequence 2 (IVS-2) which, when introduced into pCMVgag-2, redirected unspliced gag RNA into SC35-containing granules and permitted rev-independent Gag expression. These findings suggest that redirecting intranuclear RNA localization may influence gene expression. Color micrographs from this article are available for view at http//128.231.216.2/lmmhome.htm.

The Rev Axis of HIV-1 and Its Associated Host Cofactors: A Viral Window onto the Workings of Eukaryotic Posttranscriptional RNA Processing

The Rev axis of HIV is one of two key autoregulatory pathways required for viral replication and pathogenesis. The viral Rev protein interacts with its RNA target sequence, the RRE, to overcome the inhibitory effects of constitutive repressor sequences and promote nucleocytoplasmic transport and expression of viral RNAs. The Rev axis is the subject of intense scrutiny not only because it plays a central role in the viral life cycle, but also because it offers a window onto the workings of key mechanisms of posttranscriptional regulation, including splicing, polyadenylation, degradation, transport, and translation. Recent reports have conclusively demonstrated a central role for transport in the Rev mechanism and have identified cellular factors that are good candidates for mediating the transport phenomena. Other potentially involved cellular factors are being investigated. Much of the apparent heterogeneity in the observed effects of Rev may actually derive from heterogeneity in the constitutive repressor sequences rather than from heterogeneity in the mechanism of action of Rev per se. Copyright 1996 S. Karger AG, Basel

A Novel hnRNP Specifically Interacts with HIV-1 RRE RNA

We have identified and obtained the full-length clone of RREBP49, a human nuclear factor which specifically interacts with the Rev-responsive element (RRE) sequence of human immunodeficiency virus type 1. Sequence analysis revealed that RREBP49 is highly homologous to hnRNP F protein and contains three repeated RNA-binding domains. Binding assays demonstrated that Rev and RREBP49 bind to different subregions on the RRE sequence and that binding is mutually nonexclusive. Blocking of endogenous RREBP49 expression by an antisense construct increases Rev activity in CV-1 cells, indicating that RREBP49 and Rev may play antagonistic roles in HIV-1 replication. RREBP49 may function as a splicing factor or a nuclear retention factor for unspliced mRNAs. However, only a slight decrease of Rev activity was observed when exogenous RREBP49 was introduced into CV-1 cells by pSVL-RREBP49 expression vector. This may be explained by a high endogenous level of RREBP49 which is above optimal. Alternatively, additional cellular factors may be required for RREBP49-mediated inhibition of Rev. Copyright 1996 S. Karger AG, Basel

A non-canonical base pair within the human immunodeficiency virus rev-responsive element is involved in both rev and small molecule recognition

BACKGROUND

Human immunodeficiency virus (HIV) replication depends on the interaction of an HIV regulatory protein, Rev, with a viral RNA element (the Rev-responsive element, RRE). The high affinity RRE core region contains a non-canonical base pair (G48:G71) that is important for Rev recognition. Aminoglycoside antibiotics, specifically neomycin B, bind to the RRE and selectively block Rev-RRE interactions in vivo and in vitro. We attempted to generate an in vitro model for the establishment of HIV-1 resistance to neomycin B.

RESULTS

We have used in vitro genetic selection to evolve RRE variants that bind to Rev in the presence of neomycin B. Most of the RRE variants selected in the presence of 10 microM neomycin B contain a G48:G71 to A48:A71 substitution. Those selected in 100 microM neomycin B contain either C:A or A:A substitutions at this position. Binding constants for the interaction of neomycin B with the wild-type RRE and a subset of the selected RRE variants were determined using a novel ultrafiltration procedure.

CONCLUSIONS

A purine-purine base pair within the bulge region of the RRE core elements is critical for neomycin B binding as well as Rev binding. RRE variants that survive in high concentrations of neomycin do so either by binding Rev better than wild-type (this correlates with the sequence A48:A71) or by binding neomycin poorly (correlating with the sequence C48:A71). Other sequences must also influence both Rev and neomycin B binding.

RNA aptamers selected to bind human immunodeficiency virus type 1 Rev in vitro are Rev responsive in vivo

RNA aptamers (binding sequences) that can interact tightly and specifically with the human immunodeficiency virus type 1 Rev protein have previously been selected from random sequence pools. Although the selected sequences compete with the wild-type Rev-binding element (RBE) in vitro, it was not known whether they would be able to functionally replace the RBE in vivo. Two aptamers that were different from the wild-type RBE in terms of both primary sequence and secondary structure were inserted into the full-length Rev-responsive element (RRE) in place of the RBE. The hybrid RREs were assayed for their ability to mediate Rev function in vivo using a reporter system. The aptamers were found to be functionally equivalent to the wild-type element when the assay system was saturated with Rev and better than the wild-type element when Rev was limiting. These results demonstrate that the affinity of the primary Rev-binding element rather than its particular sequence may be most responsible for conferring Rev responsiveness on viral mRNAs. Moreover, the fact that increased binding ability can lead to increased Rev responsiveness suggests that cellular factors do not directly influence the Rev:RBE interaction. Finally, since sequences distinct from the RBE are found to be Rev responsive, it may be possible for the RBE to readily mutate in response to drugs or gene therapy reagents that target the Rev:RBE interaction.

Efficient expression of the human papillomavirus type 16 L1 protein in epithelial cells by using Rev and the Rev-responsive element of human immunodeficiency virus or the cis-acting transactivation element of simian retrovirus type 1

Production of the human papillomavirus (HPV) late gene products L1 and L2 is limited to terminally differentiated keratinocytes. Here, we demonstrate that mRNA encoding the HPV-16 L1 capsid protein contains cis-acting RNA elements that inhibit expression at the posttranscriptional level. While cytoplasmic L1 mRNA is detectable in transfected HeLa cells, L1 protein is not produced. We have identified at least one major inhibitory element that is located within the L1 open reading frame, whereas another negative element had been reported to lie in the 3'-untranslated region of L1. The presence of these elements may explain the lack of HPV late gene expression in undifferentiated epithelial cells. Efficient production of HPV-16 L1 could be achieved with posttranscriptional regulatory elements of human immunodeficiency virus type 1 or simian retrovirus type 1. L1 protein was expressed in the presence of human immunodeficiency virus type 1 Rev from hybrid mRNAs containing the RNA binding site for Rev (Rev-responsive element). In addition, we have achieved efficient expression of L1 from hybrid mRNAs containing a cis-acting transactivation element from simian retrovirus type 1. Our data show that HPV-16 L1 protein production is regulated posttranscriptionally. This regulated expression may allow virus production in terminally differentiated epithelial cells and is probably a conserved and important mechanism for HPV expression.

Requirement of N-terminal amino acid residues of gp41 for human immunodeficiency virus type 1-mediated cell fusion

An expression vector was designed to test the structural requirements of the gp41 N terminus for human immunodeficiency virus type 1-induced membrane fusion. Mutations in the region coding for the N terminus of gp41 were found to disrupt glycoprotein expression because of deleterious effects on the Rev-responsive element (RRE). Insertion of an additional RRE in the 3'-noncoding sequence of env made possible efficient glycoprotein expression, irrespective of the mutations introduced into the RRE in the natural location. This permitted the insertion of the unique restriction site SpeI within the N-terminal sequences of gp41, allowing convenient and efficient mutation of the gp41 N terminus by using double-stranded synthetic oligonucleotides. Mutants with deletions of 1 to 7 amino acids of the N terminus were constructed. Expression and cleavage of all mutants were confirmed by Western immunoblot analysis with anti-gp41 antibodies. The capability of mutants to induce membrane fusion was monitored following transfection of HeLa-T4+ cell lines with wild-type and mutant expression vectors by electroporation and microinjection. The efficiency of cell-fusing activity decreased drastically with deletion of 3 and 4 amino acids and was completely lost with deletion of 5 amino acids. Cotransfection of the parent and mutant expression vectors resulted in reduced cell-fusing activity. The extent of this dominant interference by mutant glycoprotein paralleled the decrease in cell-fusing activity of the mutants alone. This suggests the existence of a specific N-terminal structure required for fusing activity. However, there does not appear to be a stringent requirement for the precise length of the N terminus. This finding is supported by the length variation of this region among natural human immunodeficiency virus type 1 isolates and is in contrast to the apparent stringency in the length of analogous N-terminal structures of influenza A virus and paramyxovirus fusion glycoproteins.

Continuous propagation of RRE(-) and Rev(-)RRE(-) human immunodeficiency virus type 1 molecular clones containing a cis-acting element of simian retrovirus type 1 in human peripheral blood lymphocytes

Molecular clones of human immunodeficiency virus type 1 that contained either 37 point mutations in the Rev-responsive element (RRE) that did not affect the overlapping env reading frame or both a mutated RRE and two mutations that eliminated Rev were constructed. The mutations in the RRE were shown to remove both negative and Rev-inducible positive effects of the RRE on gene expression (G. Nasioulas, A. S. Zolotukhin, C. Tabernero, L. Solomin, C. P. Cunningham, G. N. Pavlakis, and B. K. Felber, J. Virol. 68:2986-2993, 1994). Upon insertion of a cis-acting element of simian retrovirus type 1 (SRV-1) into these clones, both RRE(-) and Rev(-)RRE(-) clones were expressed efficiently. The element of SRV-1 has properties similar to those of the recently identified element of Mason-Pfizer monkey virus (M. Bray, S. Prasad, J. W. Dubay, E. Hunter, K.-T. Jeang, D. Rekosh, and M.-L. Hammarskjold, Proc. Natl. Acad. Sci. USA 4:1256-1260, 1994). We demonstrated that virus preparations produced after transfections of these SRV-1 element-containing molecular clones in human cells were infectious after cell-free transmission, that they replicated about 5 to 10 times less efficiently than wild-type virus, and that they were propagated continuously for more than 7 months in human peripheral blood mononuclear cells. Growth characteristics and sequence analysis of these viruses after long-term culture demonstrated that no RRE(+)Rev(+) revertants developed. These data demonstrate that human immunodeficiency virus type 1 Rev and RRE can be replaced by heterologous regulatory systems, resulting in efficient virus production. The resulting Rev(-)RRE(-) virus can be prepared and propagated efficiently in tissue culture and can be used for further studies of the life cycle of the virus. The data also suggest that Rev acts exclusively through the RRE interaction and that it does not have any additional essential function in the life cycle of the virus.

1H NMR studies of the high-affinity Rev binding site of the Rev responsive element of HIV-1 mRNA: base pairing in the core binding element

1H NMR studies of a 30-nucleotide RNA oligonucleotide (RBE3), which contains a high-affinity binding site for Rev of the HIV-1 Rev responsive element (RRE), two derivatives of RBE3 (RBE3AA and RBE3-A), and the complex of RBE3 with peptides derived from the RNA binding domain of HIV-1 Rev, are presented. The high-affinity binding site of the RRE consists of an asymmetric internal loop and surrounding Watson-Crick base pairs. In the wild-type RRE, one of the stems is closed by a loop; this is replaced in REB3 by the stable UUCG tetraloop. NOE data suggest that the internal loop of the free RNA contains structural features that have been predicted on the basis of in vitro selection experiments [Bartel, D.P., et al. (1991) Cell 67, 529-536]. The structural features include a Gsyn.Ganti base pair, a Ganti.Aanti base pair, and a looped out U. When the Rev peptide is bound to the RNA, the base pairs in the internal loop appear to be stabilized, although the RNA chemical shifts indicate that the RNA conformation undergoes some changes when bound by Rev peptide.

Selection and design of high-affinity RNA ligands for HIV-1 Rev

We have used in vitro selection to isolate minimal, high-affinity RNA ligands for the Rev protein of HIV-1. Sequence analysis reveals that the tightest binding aptamers exhibit some similarity to a Rev-binding element (RBE) localized within the Rev-responsive element (RRE), but also contain novel sequence and structural motifs. A short helical stem and bulged nucleotides (nt) CUC ... UYGAG that have no counterpart in the wild-type (wt) element contribute to high-affinity binding. We have designed and synthesized a short (37 nt) RNA molecule that incorporates this motif; this RNA ligand has from three- to fivefold tighter binding than the full-length wt element, and up to 16-fold tighter than minimal wt RBEs. A guanosine:guanosine pairing that is postulated to occur in the wt element has been altered to other base pairings in the context of our optimized minimal element. RNAs that contain non-Watson-Crick base pairings, that can be modeled as isosteric to the wt G:G pair, bind Rev up to 160-fold tighter than elements that contain canonical Watson-Crick pairings or non-isosteric mismatches. These results support the hypothesis that Rev recognizes structural features associated with a non-Watson-Crick base pair.

Selective optimization of the Rev-binding element of HIV-1

RNA molecules that can bind to the Rev protein of HIV-1 have been isolated from random sequence nucleic acid pools based on a minimal Rev-binding element (RBE) found within the Rev Responsive Element (RRE). While the selected sequences are related to the wild-type element, they also contain substitutions that allow them to bind Rev up to 10-fold better in vitro. A hypothesized homopurine pairing at G48:G71 is generally replaced by A48:A71; the occasional selection of C48:A71 suggests that R71 may be in a syn conformation. These data support the structural model for the RBE originally proposed by Bartel et al. (1). Additional interactions with the Rev protein are promoted by the sequence CUC ... UYGAG, found in one class of high-affinity aptamers, but absent from the wild-type element. Within each class of aptamers different residues and substructures covary with one another to generate optimal Rev-binding surfaces. The interdependencies of different nucleotide substitutions suggest structural models for both the wild-type RBE and the selected high-affinity aptamers.

Inhibition of Rev activity and human immunodeficiency virus type 1 replication by antisense oligodeoxynucleotide phosphorothioate analogs directed against the Rev-responsive element

The interaction between the Rev protein of human immunodeficiency virus type 1 and its highly structured and conserved RNA target, the Rev-responsive element, is required for virus replication. We demonstrate that antisense oligodeoxynucleotide phosphorothioate analogs directed against the Rev-responsive element effectively inhibit Rev activity, as well as human immunodeficiency virus type 1 replication, and are candidates for antiviral therapy.

RNA recognition by the human immunodeficiency virus Tat and Rev proteins

The human immunodeficiency virus (HIV-1) regulatory proteins, Tat and Rev, are important potential targets for the development of new drug therapies against HIV infection. Both proteins are highly specific RNA-binding proteins that recognize cis-acting regulatory elements in the viral mRNAs. These interactions are fascinating paradigms of a new principle of RNA recognition in which the protein makes contact with functional groups displayed in a distorted major groove of an RNA duplex.

The RRE of human immunodeficiency virus type 1 contributes to cell-type-specific viral tropism

As part of a general program investigating the mechanism of the Rev axis of human immunodeficiency virus type 1 (HIV-1) autoregulation, a series of proviral HIV-1 mutants which differ from the parental HXB2 strain at selected positions within the RRE were constructed. All of the mutations were designed to perturb the RRE by introducing local helix disruptions without altering the coding potential of the overlapping envelope open reading frame. Viral replication in various cell types was monitored by a cell supernatant reverse transcriptase assay and Northern (RNA blot) analysis. All proviral RRE mutants displayed at least some impairment in replication. However, the relative impairment varied drastically among the various cell types tested. This suggests that the RRE may contribute to cell-type-specific viral tropism.

The search for structure-specific nucleic acid-interactive drugs: effects of compound structure on RNA versus DNA interaction strength

The RNA genomes of a number of pathogenic RNA viruses, such as HIV-1, have extensive folded conformations with imperfect A-form duplexes that are essential for virus function and could serve as targets for structure-specific antiviral drugs. As an initial step in the discovery of such drugs, the interactions with RNA of a wide variety of compounds, which are known to bind to DNA in the minor groove, by classical or by threading intercalation, have been evaluated by thermal melting and viscometric analyses. The corresponding sequence RNA and DNA polymers, poly(A).poly(U) and poly(dA).poly(dT), were used as test systems for analysis of RNA binding strength and selectivity. Compounds that bind exclusively in the minor groove in AT sequences of DNA (e.g., netropsin, distamycin, and a zinc porphyrin derivative) do not have significant interactions with RNA. Compounds that bind in the minor grove in AT sequences of DNA but have other favorable interactions in GC sequences of DNA (e.q., Hoechst 33258, DAPI, and other aromatic diamidines) can have very strong RNA interactions. A group of classical intercalators and a group of intercalators with unfused aromatic ring systems contain compounds that intercalate and have strong interactions with RNA. At this time, no clear pattern of molecular structure that favors RNA over DNA interactions for intercalators has emerged. Compounds that bind to DNA by threading intercalation generally bind to RNA by the same mode, but none of the threading intercalators tested to date have shown selective interactions with RNA.

Prediction of common folding structures of homologous RNAs

We have developed an algorithm and a computer program for simultaneously folding homologous RNA sequences. Given an alignment of M homologous sequences of length N, the program performs phylogenetic comparative analysis and predicts a common secondary structure conserved in the sequences. When the structure is not uniquely determined, it infers multiple structures which appear most plausible. This method is superior to energy minimization methods in the sense that it is not sensitive to point mutation of a sequence. It is also superior to usual phylogenetic comparative methods in that it does not require manual scrutiny for covariation or secondary structures. The most plausible 1-5 structures are produced in O(MN2 + N3) time and O(N2) space, which are the same requirements as those of widely used dynamic programs based on energy minimization for folding a single sequence. This is the first algorithm probably practical both in terms of time and space for finding secondary structures of homologous RNA sequences. The algorithm has been implemented in C on a Sun SparcStation, and has been verified by testing on tRNAs, 5S rRNAs, 16S rRNAs, TAR RNAs of human immunodeficiency virus type 1 (HIV-1), and RRE RNAs of HIV-1. We have also applied the program to cis-acting packaging sequences of HIV-1, for which no generally accepted structures yet exist, and propose potentially stable structures. Simulation of the program with random sequences with the same base composition and the same degree of similarity as the above sequences shows that structures common to homologous sequences are very unlikely to occur by chance in random sequences.

Recognition of the high affinity binding site in rev-response element RNA by the human immunodeficiency virus type-1 rev protein

The Human Immunodeficiency Virus type-1 rev protein binds with high affinity to a bubble structure located within the rev-response element (RRE) RNA in stemloop II. After this initial interaction, additional rev molecules bind to the RRE RNA in an ordered assembly process which requires a functional bubble structure, since mutations in the bubble sequence that reduce rev affinity block multiple complex formation. We have used synthetic chemistry to characterize the interaction between rev protein and its high affinity binding site. A minimal synthetic duplex RNA (RBC6) carrying the bubble and 12 flanking base pairs is able to bind rev with 1 to 1 stoichiometry and with high affinity. When the bubble structure is inserted into synthetic RNA molecules carrying longer stretches of flanking double-stranded RNA, rev forms additional complexes resembling the multimers observed with the RRE RNA. The ability of rev to bind to RBC6 analogues containing functional group modifications on base and sugar moieties of nucleoside residues was also examined. The results provide strong evidence that the bubble structure contains specific configurations of non-Watson--Crick G:G and G:A base pairs and suggest that high affinity recognition of RRE RNA by rev requires hydrogen bonding to functional groups in the major groove of a distorted RNA structure.

Human immunodeficiency virus type 1 Rev activation can be achieved without Rev-responsive element RNA if Rev is directed to the target as a Rev/MS2 fusion protein which tethers the MS2 operator RNA

The posttranscriptional trans activation of unspliced or partially spliced human immunodeficiency virus RNAs by the Rev regulatory protein is crucial for virus replication and is dependent on sequence-specific RNA binding by Rev. The cognate RNA target of Rev is contained within a highly structured, 244-nucleotide Rev-responsive element (RRE) RNA in the viral env gene. Here, we show that specific interaction with the RRE is not an absolute requirement for Rev function. When the RRE is replaced by a heterologous MS2 phage operator sequence, Rev will facilitate the cytoplasmic expression of human immunodeficiency virus mRNAs containing this sequence if directed to the MS2 operator via the RNA binding motif of the MS2 phage coat protein (MS-C) as a Rev/MS-C fusion protein. Rev/MS-C efficiently activated both RRE and MS2 targets. A mutation in the MS2 operator that abolished the coat protein binding in vitro rendered the mutant RNA nonresponsive to the fusion protein in vivo. Notwithstanding that Rev can be tethered to the viral RNAs via another RNA binding motif, the structural integrity of the N terminus of Rev was still required for optimal trans activation.