Design of artificial pepetides that recognize the HIV RRE IIB RNA.

Peptide nucleic acid (PNA) conjugated peptides, derived from HIV-1 Rev, were designed and synthesized in order to construct molecules that recognize HIV RRE IIB RNA. The competitive binding analyses using fluorescent Rev peptide revealed that the PNA unit on the peptide affected the RNA binding.     

Construction of HIV Rev peptides containing peptide nucleic acid that bind HIV RRE IIB RNA

Peptides containing peptide nucleic acid (PNA) have been designed and synthesized to construct molecules recognizing a bulge or a loop structure of RNA. Such peptides were here designed from the HIV Rev protein that can bind the stem-loop IIB of the Rev responsive element (RRE) RNA. Variations of PNA modulated the binding affinities of the peptides to RRE IIB RNA.     

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.     

Construction of peptides with nucleobase amino acids: design and synthesis of the nucleobase-conjugated peptides derived from HIV-1 Rev and their binding properties to HIV-1 RRE RNA

In order to develop a novel molecule that recognizes a specific structure of RNA, we have attempted to design peptides having L-alpha-amino acids with a nucleobase at the side chain (nucleobase amino acid (NBA)), expecting that the function of a nucleobase which can specifically recognize a base in RNA is regulated in a peptide conformation. In this study, to demonstrate the applicability of the NBA units in the peptide to RNA recognition, we designed and synthesized a variety of NBA-conjugated peptides, derived from HIV-1 Rev. Circular dichroism study revealed that the conjugation of the Rev peptide with an NBA unit did not disturb the peptide conformation. RNA-binding affinities of the designed peptides with RRE IIB RNA were dependent on the structure of the nucleobase moieties in the peptides. The peptide having the cytosine NBA at the position of the Asn40 site in the Rev showed a higher binding ability for RRE IIB RNA, despite the diminishing the Asn40 function. Furthermore, the peptide having the guanine NBA at the position of the Arg44 site, which is the most important residue for the RNA binding in the Rev, bound to RRE IIB RNA in an ability similar to Rev34-50 with native sequence. These results demonstrate that an appropriate NBA unit in the peptide plays an important role in the RNA binding with a specific contact such as hydrogen bonding, and the interaction between the nucleobase in the peptide and the base in the RNA can enhance the RNA-binding affinity and specificity.     

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.     

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.     

Water, Shape Recognition, Salt Bridges, and Cation-Pi Interactions Differentiate Peptide Recognition of the HIV Rev-Responsive Element

Recognition of the human immunodeficiency virus Rev-responsive element (RRE) RNA by the Rev protein is an essential step in the viral life cycle. Formation of the Rev-RRE complex signals nucleocytoplasmic export of unspliced and partially spliced viral RNA. Essential components of the complex have been localized to a minimal arginine-rich Rev peptide and stem IIB of RRE. In vitro selection studies have identified a synthetic peptide known as RSG 1.2 that binds with better specificity and affinity to RRE than the Rev peptide. NMR structures of both peptide-RNA complexes of Rev and RSG 1.2 bound to RRE stem IIB have been solved and reveal gross structural differences between the two bound complexes. Molecular dynamics simulations of the Rev and RSG 1.2 peptides in complex with RRE stem IIB have been simulated to better understand on an atomic level how two arginine-rich peptides of similar length recognize the same sequence of RNA with such different structural motifs. While the Rev peptide employs some base-specific hydrogen bonding for recognition of RRE, shape recognition, through contact with the sugar-phosphate backbone, and cation-pi interactions are also important. Molecular dynamics simulations suggest that RSG 1.2 binds more tightly to the RRE sequence than Rev by forming more base-specific contacts, using water to mediate peptide-RNA contacts, and is held in place by a strong salt bridge network spanning the major groove of the RNA.     

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.     

Mechanism of neomycin and Rev peptide binding to the Rev responsive element of HIV-1 as determined by fluorescence and NMR spectroscopy

Rev is an essential HIV-1 regulatory protein that binds the Rev responsive element (RRE) within the env gene of the HIV-1 RNA genome and is involved in transport of unspliced or partially spliced viral mRNA from the cell nucleus to the cytoplasm. Previous studies have shown that a short alpha-helical peptide derived from Rev (Rev 34-50), and a truncated form of the RRE sequence provide a useful in vitro system to study this interaction while still preserving the essential aspects of the native complex. We have selectively incorporated the fluorescent probe 2-aminopurine 2'-O-methylriboside (2-AP) into the RRE sequence in nonperturbing positions (A68 and U72) such that the binding of both Rev peptide and aminoglycoside ligands could be characterized directly by fluorescence methods. Rev peptide binding to the RRE-72AP variant resulted in a 2-fold fluorescence increase that provided a useful signal to monitor this binding interaction (K(D) = 20 +/- 7 nM). Using stopped-flow kinetic measurements, we have shown that specific Rev peptide binding occurs by a two-step process involving diffusion-controlled encounter, followed by isomerization of the RNA. Using the RRE-68AP and -72AP constructs, three classes of binding sites for the aminoglycoside neomycin were unambiguously detected. The first site is noninhibitory to Rev binding (K(D) = 0.24 +/- 0.040 microM), the second site inhibited Rev binding in a competitive fashion (K(D) = 1. 8 +/- 0.8 microM), and the third much weaker site (or sites) is attributed to nonspecific binding (K(D) >/= 40 microM). Complementary NMR measurements have shown that neomycin forms both a specific binary complex with RRE and a specific ternary complex with RRE and Rev. NMR data further suggest that neomycin occupies a similar high-affinity binding site in both the binary and ternary complexes, and that this site is located in the lower stem region of RRE.     

Cellular activity of Rev response element RNA targeting metallopeptides

The cellular chemistry of metallopeptide complexes designed to target and inactivate an HIV Rev response element (RRE) RNA sequence in vivo has been evaluated by use of an efficient cellular fluorescence assay. Transcribed messenger RNA encoding the green fluorescent protein (GFP) that includes a target RNA sequence is sensitive to cleavage chemistry mediated by metal derivatives of GGH(G) _x TRQARRNRR RRWRERQR (x = 0, 1, 2, 4, 6). This results in a significant decrease in expression of GFP that can be quantified by fluorimetry. Optimal inactivation of the target RRE RNA was achieved with linkers where x = 0 or 1. Neither the Rev control peptide (lacking metal-binding or linker sequences) nor the metal-binding motif alone had any significant effect. Consequently, both the cleavage motif and the RNA targeting motif are essential to promote cellular cleavage of the target RRE RNA. However, target inactivation was also observed in experiments with metal-free peptide, consistent with recruitment of intracellular metal ion by the peptide following cellular uptake, with subsequent cleavage of the RRE target RNA. The RRE RNA cleavage activities of metallopeptide complexes were further confirmed by in vitro experiments and mammalian cell assays.     

Evolvability of the mode of peptide binding by an RNA

The HIV Rev-response element (RRE) RNA binds strongly to two unrelated peptides, the HIV Rev peptide and an RRE-binding aptamer, the RSG-1.2 peptide, at a similar site, but using distinct sets of interactions. In this study, the nucleotide base requirements for the binding of the RRE to the Rev and RSG-1.2 peptides were determined by selection of Rev- and RSG-1.2-binding RRE variants using a bacterial reporter system. As a result, distinct differences in the bases necessary for binding the two peptides were found in the upper stem of the RRE. Strikingly, single nucleotide changes in this region were found to switch the peptide-binding specificity of the RRE from a bifunctional Rev- and RSG-1.2-binding mode to either a Rev-specific or a RSG-1.2- specific mode, demonstrating how an RNA can evolve alternative binding strategies in discrete steps without intermediate loss of function. This evolvability of the mode of peptide binding by an RNA presumably reflects the multidimensionality of conformational space that a given RNA has available for ligand recognition, which may have been utilized in the evolution of RNA-polypeptide complexes.     

Aminoglycoside antibiotics, neamine and its derivatives as potent inhibitors for the RNA-protein interactions derived from HIV-1 activators

Neamine derivatives which have an arginine (RN), a pyrene (PCN) and both pyrene and arginine (PRN) have been prepared and their binding toward the RNA fragments derived from HIV-1 activator region, TAR and RRE RNA were examined. Among them, PRN bound either TAR RNA or RRE RNA with equivalent binding affinities as Tat and Rev peptide, respectively.     

Specific binding of a basic peptide from HIV-1 Rev.

Human immunodeficiency virus type I (HIV-1) encodes a regulatory protein, Rev, which is required for cytoplasmic expression of incompletely spliced viral mRNA. Rev activity is mediated through specific binding to a cis-acting Rev responsive element (RRE) located within the env region of HIV-1. A monomer Rev binding site corresponding to 37 nucleotides of the RRE (IIB RNA) was studied by RNA footprinting, modification interference experiments and mutational analysis. Surprisingly, a 17 amino acid peptide, corresponding to the basic domain of Rev, binds specifically to this site at essentially identical nucleotides and probably induces additional base pairing. The Rev protein and related peptide interact primarily with two sets of nucleotides located at the junction of single and double stranded regions, and at an additional site located within a helix. This suggests that the domains of proteins responsible for specific RNA binding can be remarkably small and that the interaction between RNA and protein can probably induce structure in both constituents.     

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.     

Assignment and modeling of the Rev Response Element RNA bound to a Rev peptide using 13C-heteronuclear NMR

Summary The Rev Response Element (RRE) RNA-Rev protein interaction is important for regulation of gene expression in the human immunodeficiency virus. A model system for this interaction, which includes stem IIB of the RRE RNA and an arginine-rich peptide from the RNA-binding domain of Rev, was studied using multidimensional heteronuclear NMR. Assignment of the RNA when bound to the peptide was obtained from NMR experiments utilizing uniformly and specifically ¹³C-labeled RNA. Isotopic filtering experiments on the specifically labeled RNA enabled unambiguous assignment of unusual nonsequential NOE patterns present in the internal loop of the RRE. A three-dimensional model of the RNA in the complex was obtained using restrained molecular dynamics calculations. The internal loop contains two purine-purine base pairs, which are stacked to form one continuous helix flanked by two A-form regions. The formation of a G-G base pair in the internal loop requires an unusual structure of the phosphate backbone. This structural feature is consistent with mutational data as being important for the binding of Rev to the RRE. The G-G base pair may play an important role in opening the normally narrow major groove of A-form RNA to permit binding of the Rev basic domain.     

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.     

Facile conversion of RNA aptamers to modular fluorescent sensors with tunable detection wavelengths

A GTP aptamer was converted to a modular fluorescent GTP sensor by conjugation of RRE (Rev responsive element) RNA and successive complex formation with a fluorophore-modified Rev peptide. Structural changes associated with substrate binding in the RNA aptamer were successfully transduced into changes in fluorescence intensity because of the modular structure of ribonucleopeptides. A simple modular strategy involving conjugation of a fluorophore-modified ribonucleopeptide to the stem region of an RNA aptamer deduced from secondary structural information helps produce fluorescent sensors, which allow tuning of excitation and detection wavelengths through the replacement of the fluorophore at the N-terminal of the Rev peptide.