A high-throughput screening utilizing intramolecular fluorescence resonance energy transfer for the discovery of the molecules that bind HIV-1 TAR RNA specifically

A 16-residue peptide, including the Tat(49-57) sequence was labeled with a fluorescein and a tetramethylrhodamine at its N- and C-terminus, respectively. This double dye-labeled peptide was prepared as a tracer for high-throughput screening utilizing intramolecular fluorescence resonance energy transfer (FRET). The binding of the competitor molecules for HIV-1 TAR RNA were monitored and dissociation constants of those molecule were determined by using this tracer. This novel screening system might be useful to discover the drug for HIV-1 TAR RNA.     

Selection of TAR RNA-binding chameleon peptides by using a retroviral replication system

The interaction between the arginine-rich motif (ARM) of the human immunodeficiency virus (HIV) Tat protein and TAR RNA is essential for Tat activation and viral replication. Two related lentiviruses, bovine immunodeficiency virus (BIV) and Jembrana disease virus (JDV), also require Tat ARM-TAR interactions to mediate activation, but the viruses have evolved different RNA-binding strategies. Interestingly, the JDV ARM can act as a "chameleon," adopting both the HIV and BIV TAR binding modes. To examine how RNA-protein interactions may evolve in a viral context and possibly to identify peptides that recognize HIV TAR in novel ways, we devised a retroviral system based on HIV replication to amplify and select for RNA binders. We constructed a combinatorial peptide library based on the BIV Tat ARM and identified peptides that, like the JDV Tat ARM, also function through HIV TAR, revealing unexpected sequence characteristics of an RNA-binding chameleon. The results suggest that a retroviral screening approach may help identify high-affinity TAR binders and may provide new insights into the evolution of RNA-protein interactions.     

Characterization of the solution conformations of unbound and Tat peptide-bound forms of HIV-1 TAR RNA.

Basic peptides from the carboxy terminus of the HIV-1 Tat protein bind to the apical stem-loop region of TAR RNA with high affinity and moderate specificity. The conformations of the unbound and 24 residue Tat peptide (Tfr24)-bound forms of TAR RNA have been characterized by NMR spectroscopy. The unbound form of TAR exists in major and minor forms having different trinucleotide bulge conformations. A specific TAR RNA conformational change is observed upon complex formation with Tfr24, consisting of coaxial stacking of helical stems and base triple formation. A U23-A27-U38 base triple is proposed based on exchangeable proton NMR data, where U23 forms a base pair with A27 in the major groove. No evidence for base triple formation was found for Tat peptides in which lysine residues are extensively substituted for arginine.     

Oligonucleotide inhibition of the interaction of HIV-1 Tat protein with the trans-activation responsive region (TAR) of HIV RNA

The interaction of HIV-1 Tat protein with its recognition sequence, the trans-activation responsive region TAR is a potential target for drug discovery against HIV infection. We show by use of an in vitro competition filter binding interference assay that synthetic oligodeoxyribonucleotides complementary to the HIV-1 TAR RNA apical stem-loop and bulge region inhibit the binding of Tat protein or a Tat peptide (residues 37-72) better than two small molecules that have been shown to bind TAR RNA, Hoechst 33258 and neomycin B. The inhibition is not sensitive to length between 13 and 16 residues or precise positioning but shorter oligonucleotides are less effective. Enhanced inhibition was obtained for a 16-mer 2'-O-methyl oligoribonucleotide but not for C5-propyne pyrimidine-substituted oligonucleotides. Control non-antisense oligonucleotides were occasionally also effective in filter binding interference but only the complementary antisense 2'-O-methyl oligoribonucleotide was effective in gel mobility shift assays in direct TAR binding or in interference with Tat peptide binding to the TAR stem-loop. This is the first demonstration of effective inhibition of the Tat-TAR interaction by nuclease-stabilized oligonucleotide analogues.     

Probing Tat peptide-TAR RNA interactions by psoralen photo-cross-linking

Replication of human immunodeficiency virus type 1 (HIV-1) requires specific interactions of Tat protein with the trans-activation responsive region (TAR) RNA, a 59-base stem-loop structure located at the 5'-end of all HIV mRNAs. We have used a site-specific cross-linking method based on psoralen photochemistry to determine the effect of core residues from the Tat sequence on the protein orientation in the Tat-TAR complex and on the specificity of Tat-TAR binding. We synthesized two Tat fragments, Tat(42-72) and Tat(37-72), and incorporated a psoralen-modified amino acid at position 41 during solid-phase assembly of the peptides. We used these psoralen-Tat conjugates to form specific complexes with TAR RNA. Upon near-ultraviolet irradiation (360 nm), psoralen-Asp41-Tat(37-72) cross-linked to a single site in the TAR RNA sequence. The RNA-protein complex was purified and the cross-link site on TAR RNA was determined by primer extension analysis, which revealed that Asp41 of Tat is close to U42 of the lower stem region of TAR RNA. Specificity of the RNA-peptide cross-linking reactions was determined by competition experiments. Our results show that the addition of only four residues (Cys37-Thr40) from the Tat core region significantly enhanced the specificity of the Tat peptide-TAR interactions without altering the site or chemical nature of the cross-link. These studies provide new insights into RNA-protein recognition that could be useful in designing peptidomimetics for RNA targeting. Such psoralen-peptide conjugates provide a new class of probes for sequence-specific protein-nucleic acid interactions and could be used to selectively control gene expression or to induce site-directed mutations.     

Circular dichroism studies suggest that TAR RNA changes conformation upon specific binding of arginine or guanidine.

Short basic peptides from the HIV Tat protein bind specifically to a bulge region in TAR RNA, with a single arginine residue providing the only sequence-specific contact. The free amino acid arginine also binds specifically to TAR. Previous circular dichroism (CD) experiments suggested that peptide binding induces a conformational change in TAR. Here we confirm this observation using single arginine-containing peptides and show that arginine or guanidine binding also induces a conformational change in TAR. A peptide containing a single arginine within a stretch of histidines (CYHHHRHHHHHA) shows pH-dependent binding and a corresponding change in TAR conformation, as detected by a decrease in the CD signal at 265 nm. Arginine and guanidine, which bind to TAR with apparent Kd's of approximately 1.5 mM, induce similar CD changes. In contrast, lysine, which does not bind specifically to TAR, has no effect. Mutants of TAR that abolish specific binding (a U-->C substitution in the three-nucleotide bulge, a deletion of the bulge, or an A-U to U-A base pair change above the bulge) show no change in the CD signal upon binding of peptides, arginine, or guanidine. The results suggest that binding of a single guanidinium group to a specific site in TAR induces a change in RNA conformation.     

Polyamidoamine dendrimers inhibit binding of Tat peptide to TAR RNA

The binding of polyamidoamine (PAMAM) dendrimer or Tat peptide to trans-acting responsive element (TAR) RNA has been studied using microgravimetric quartz crystal microbalance (QCM). Experimental results showed that PAMAM dendrimer could form complexes with TAR RNA. Especially, PAMAM dendrimer could disrupt the interaction of Tat peptide with TAR RNA, which is essential for HIV-1 virus replication, suggesting that QCM is a powerful tool for studying the binding processes of Tat peptide-TAR RNA and drug-TAR RNA and has great significance for the design of new drugs. An equation to measure the binding ability between TAR RNA and other species has been proposed.     

Identification of a novel HIV-1 TAR RNA bulge binding protein.

The Tat protein binds to TAR RNA to stimulate the expression of the human immunodeficiency virus type 1 (HIV-1) genome. Tat is an 86 amino acid protein that contains a short region of basic residues (aa49-aa57) that are required for RNA binding and TAR is a 59 nucleotide stem-loop with a tripyrimidine bulge in the upper stem. TAR is located at the 5' end of all viral RNAs. In vitro, Tat specifically interacts with TAR by recognising the sequence of the bulge and upper stem, with no requirement for the loop. However, in vivo the loop sequence is critical for activation, implying a requirement for accessory cellular TAR RNA binding factors. A number of TAR binding cellular factors have been identified in cell extracts and various models for the function of these factors have been suggested, including roles as coactivators and inhibitors. We have now identified a novel 38 kD cellular factor that has little general, single-stranded or double-stranded RNA binding activity, but that specifically recognises the bulge and upper stem region of TAR. The protein, referred to as BBP (bulge binding protein), is conserved in mammalian and amphibian cells and in Schizosaccharomyces pombe but is not found in Saccharomyces cerevisiae. BBP is an effective competitive inhibitor of Tat binding to TAR in vitro. Our data suggest that the bulge-stem recognition motif in TAR is used to mediate cellular factor/RNA interactions and indicates that Tat action might be inhibited by such competing reactions in vivo.     

Unusual structure of the human immunodeficiency virus type 1 trans-activation response element.

The trans-activation response element (TAR) of human immunodeficiency virus type 1 is a structured RNA consisting of the first 60 nucleotides of all human immunodeficiency virus type 1 RNAs. Computer analyses and limited structural analyses indicated that TAR consists of a stem-bulge-loop structure. Mutational analyses showed that sequences in the bulge are required for Tat binding, whereas sequences in both the bulge and the loop are required for trans activation. In this study, we probed the structures of TAR and various mutants of TAR with chemical probes and RNases and used these methods to footprint a Tat peptide on TAR. Our data show that the structure of wild-type TAR is different from previously published models. The bulge, a Tat-binding site, consists of four nucleotides. The loop is structured, rather than simply single stranded, in a fashion reminiscent of the structures of the tetraloop 5'-UUCG-3' and the GNRA loop (C. Cheong, G. Varani, and I. Tinoco, Jr., Nature [London] 346:680-682, 1990; H.A. Heus and A. Pardi, Science 253:191-193, 1991). RNA footprint data indicate that three bases in the bulge are protected and suggest that a conformational change occurs upon Tat binding.     

Rotational symmetry in ribonucleotide strand requirements for binding of HIV-1 Tat protein to TAR RNA.

Transactivation of human immunodeficiency virus (HIV) gene expression requires binding of the viral Tat protein to a RNA hairpin-loop structure (TAR) which contains a two or three-nucleotide bulge. Tat binds in the vicinity of the bulge and the two adjacent duplex stems, recognising both specific sequence and structural features of TAR. Binding is mediated by an arginine-rich domain, placing Tat in the family of arginine-rich RNA binding proteins that includes other transactivators, virus capsid proteins and ribosome binding proteins. In order to determine what features of TAR allow Tat to bind efficiently to RNA but not DNA forms, we examined Tat binding to a series of RNA-DNA hybrids. We found that only one specific strand in each duplex stem region needs to be RNA, implying that interaction between Tat and a given stem may be solely or predominantly with one of the two strands. However, the essential strand is not the same one for each stem, suggesting a switch in the bound strand on opposing sides of the bulge.