HIV-1 TAR Element Research Articles

Comparative analysis of herpes simplex virus thymidine kinase gene expression potentiation via HIV-1 Tat-TAR system and cancer-specific promoters in P53(+) and P53(-) cells

Tumor-specific promoters are predominantly active and ensure expression of the gene under control exclusively in cancer cells. However, a low activity of the promoters is an essential disadvantage for their therapy usage. To achieve a higher expression level of the therapeutic gene, herpes simplex virus thymidine kinase (HSV-tk), the Tat-TAR-system being utilized by HIV-1 for increasing own gene expression was developed. A potentiating activity of tat gene under control of two different cancer-specific gene (human survivin gene and human telomerase reverse transcriptase) promoters for increasing of the HSV-tk gene expression being regulated by TAR-element was evaluated, and activity of the cancer-specific promoters in the Tat-TAR-system was compared. Co-transfection of the cells with the both constructions led to the tat protein synthesis and its affect the HIV-1 TAR-element. An expression level of HSV-tk gene ensured by the both promoters in the binary system was close to that for strong non-specific cytomegalovirus (CMV) promoter. Enzymatic activity of HSV-tk protein in cells having both elements of Tat-TAR-system was two orders of magnitude higher than that in the cells transfected with HSV-tk gene under control of the cancer-specific promoter. Notably, the effect was independent of p53-status of transfected cells: HSV-tk expression level was almost the same in p53(+) and p53(-) cells. The obtained results show that system may be used for therapy of different cancer types both p53-defective and p53-positive ones inhibiting cancer-specific promoters activity.

Cleavage of RNA oligonucleotides by aminoglycosides

A number of aminoglycoside antibiotics, and in particular neomycin B, are demonstrated to promote strand cleavage of RNA oligonucleotides (minimised HIV-1 TAR element and prokaryotic ribosomal A-site), by binding and causing sufficient distortion to the RNA backbone to render it more susceptible to intramolecular transesterification.

Strong correlation between SHAPE chemistry and the generalized NMR order parameter (S2) in RNA.

The functions of most RNA molecules are critically dependent on the distinct local dynamics that characterize secondary structure and tertiary interactions and on structural changes that occur upon binding by proteins and small molecule ligands. Measurements of RNA dynamics at nucleotide resolution set the foundation for understanding the roles of individual residues in folding, catalysis, and ligand recognition. In favorable cases, local order in small RNAs can be quantitatively analyzed by NMR in terms of a generalized order parameter, S2. Alternatively, SHAPE (selective 2'-hydroxyl acylation analyzed by primer extension) chemistry measures local nucleotide flexibility in RNAs of any size using structure-sensitive reagents that acylate the 2'-hydroxyl position. In this work, we compare per-residue RNA dynamics, analyzed by both S2 and SHAPE, for three RNAs: the HIV-1 TAR element, the U1A protein binding site, and the Tetrahymena telomerase stem loop 4. We find a very strong correlation between the two measurements: nucleotides with high SHAPE reactivities consistently have low S2 values. We conclude that SHAPE chemistry quantitatively reports local nucleotide dynamics and can be used with confidence to analyze dynamics in large RNAs, RNA-protein complexes, and RNAs in vivo.

HIV-1 TAR element is processed by Dicer to yield a viral micro-RNA involved in chromatin remodeling of the viral LTR

BackgroundRNA interference (RNAi) is a regulatory mechanism conserved in higher eukaryotes. The RNAi pathway generates small interfering RNA (siRNA) or micro RNA (miRNA) from either long double stranded stretches of RNA or RNA hairpins, respectively. The siRNA or miRNA then guides an effector complex to a homologous sequence of mRNA and regulates suppression of gene expression through one of several mechanisms. The suppression of gene expression through these mechanisms serves to regulate endogenous gene expression and protect the cell from foreign nucleic acids. There is growing evidence that many viruses have developed in the context of RNAi and express either a suppressor of RNAi or their own viral miRNA.ResultsIn this study we investigated the possibility that the HIV-1 TAR element, a hairpin structure of ~50 nucleotides found at the 5' end of the HIV viral mRNA, is recognized by the RNAi machinery and processed to yield a viral miRNA. We show that the protein Dicer, the enzyme responsible for cleaving miRNA and siRNA from longer RNA sequences, is expressed in CD4+ T-cells. Interestingly, the level of expression of Dicer in monocytes is sub-optimal, suggesting a possible role for RNAi in maintaining latency in T-cells. Using a biotin labeled TAR element we demonstrate that Dicer binds to this structure. We show that recombinant Dicer is capable of cleaving the TAR element in vitro and that TAR derived miRNA is present in HIV-1 infected cell lines and primary T-cell blasts. Finally, we show that a TAR derived miRNA is capable of regulating viral gene expression and may be involved in repressing gene expression through transcriptional silencing.ConclusionHIV-1 TAR element is processed by the Dicer enzyme to create a viral miRNA. This viral miRNA is detectable in infected cells and appears to contribute to viral latency.

Synthesis and Assay of Isoquinoline Derivatives as HIV‐1 Tat—TAR Interaction Inhibitors.

AbstractFor Abstract see ChemInform Abstract in Full Text.

Synthesis and assay of isoquinoline derivatives as HIV-1 Tat–TAR interaction inhibitors

Four new isoquinoline derivatives bearing guanidinium group or amino group-terminated side chain were synthesized to target the HIV-1 TAR element. Their abilities to bind TAR RNA and inhibit Tat–TAR RNA interaction were determined by CE analysis, a Tat-dependent HIV-1 LTR-driven CAT assay and SIV-induced syncytium evaluation.

Effects of Unpaired Nucleotides within HIV-1 Genomic Secondary Structures on Pausing and Strand Transfer

Reverse transcriptase-mediated RNA displacement synthesis is required for DNA polymerization through the base-paired stem portions of secondary structures present in retroviral genomes. These regions of RNA duplex often possess single unpaired nucleotides, or "bulges," that disrupt contiguous base pairing. By using well defined secondary structures from the human immunodeficiency virus, type 1 (HIV-1), genome, we demonstrate that removal of these bulges either by deletion or by introducing a complementary base on the opposing strand results in increased pausing at specific positions within the RNA duplex. We also show that the HIV-1 nucleocapsid protein can increase synthesis through the pause sites but not as efficiently as when a bulge residue is present. Finally, we demonstrate that removing a bulge increases the proportion of strand transfer events to an acceptor template that occur prior to complete replication of a donor template secondary structure. Together our data suggest a role for bulge nucleotides in enhancing synthesis through stable secondary structures and reducing strand transfer.

Selection by Phage Display of Peptides Targeting the HIV-1 TAR Element

As transcription regulatory element, the HIV-1 TAR RNA element is a promising target to inhibit the viral replication ; indeed, ligands of TAR RNA could prevent the transcription trans-activation process. A phage display in vitro selection was undertaken to select peptidic ligands of TAR RNA. In preliminary experiments, the selection was performed in a magnesium rich buffer (3 mM), but only phages targeted to plastic wells or streptavidin emerged ; in addition, a “super-infectious” phage present in the New England Biolabs library (SVSVGMKPSPRP) selected by others with different targets was cloned, due to a high amplification potential. In contrast, the absence of magnesium or an increasing magnesium concentration (0 to 0.5 mM) led to phage selection with 57 amino acid peptides. KDs of 420-550 nM were measured by filter binding assays ; a significant specificity was obtained when TAR target was compared with unrelated RNA targets. Surprisingly, the binding of selected peptides does not depend on the magnesium concentration.

A small circular TAR RNA decoy specifically inhibits Tat-activated HIV-1 transcription.

Linear TAR RNA has previously been used as a decoy to inhibit HIV-1 transcription in vitro and HIV-1 replication in vivo. A 48 nucleotide circular RNA containing the stem, bulge and loop of the HIV-1 TAR element was synthesized using the self-splicing activity of a group I permuted intron-exon and was tested for its ability to function as a TAR decoy in vitro. This small circular TAR molecule was exceptionally stable in HeLa nuclear extracts, whereas a similar linear TAR molecule was rapidly degraded. The TAR circle bound specifically to Tfr38, a peptide containing the TAR-binding region of Tat. The ability of Tat to trans-activate transcription from the HIV-1 promoter in vitro was efficiently inhibited by circular TAR RNA but not by TAR circles that contained either bulge or loop mutations. TAR circles did not inhibit transactivation exclusively by binding to Tat since this inhibition was not reversed by adding excess Tat to the transcription reaction. Together, these data suggest that TAR circles act as decoys that inhibit transactivation by binding to Tat and at least one cellular factor. These data also demonstrate the utility of small circular RNA molecules as tools for biochemical studies.

Functional Significance of the Dinucleotide Bulge in Stem-Loop1 and Stem-Loop2 of HIV-2 TAR RNA

Human immunodeficiency virus types 1 and 2 (HIV-1 and HIV-2) encode related proteins called Tat-1 and Tat-2, respectively, that bind directly to the TAR RNA element contained at the 5′ ends of viral transcripts and thereby stimulate transcription through an as yet unidentified mechanism. The determinants in the HIV-1 TAR element (TAR-1) that specify binding by the Tat-1 protein have been extensively characterized, while little is known about determinants in the HIV-2 TAR element (TAR-2) that specify binding by the Tat-2 protein. The HIV-2 TAR RNA element (TAR-2) is known to be composed of two stem-loop structures. A dinucleotide bulge is found in each stem of TAR-2 RNA, analogous to the crucial trinucleotide bulge in the single stem-loop of HIV- 1 TAR RNA that is the primary binding determinant for binding by the HIV-1 Tat protein. Our results of a nuclease digestion analysis demonstrated that the 5′ proximal bulge in TAR-2 is significantly less sensitive to digestion by single-strand specific nucleases than the 3′ distal bulge, suggesting that the 5′ bulge may be involved in tertiary interaction with other regions of TAR RNA. Deletion of both bulges reduced binding in vitro by the Tat-2 protein and largely abolished transactivation in vivo by Tat-2. Deletion of either bulge alone simplified the pattern of protein/RNA complexes in a gel shift assay, but did not reduce the overall binding affinity of Tat-2. Deletion of the 5′ bulge reduced Tat-2 transactivation in vivo to a level approximately 30% that of wild-type TAR-2, while deletion of the 3′ bulge had no measurable effect in vivo. Our result suggest that each dinucleotide bulge specifies a Tat-2 binding site, but in the wild-type TAR-2 element the 3′ bulge binding site does not appear to be utilized in vivo.

An NMR study of the HIV-1 TAR element hairpin.

The TAR hairpin is an important part of the 5' long terminal repeat of HIV-1 and appears to be recognized by a cellular protein. A 14-base model of the native TAR hairpin 5'-GAGC[CUGGGA]-GCUC-3' (loop bases in square brackets) has been studied by proton, phosphorus, and natural abundance carbon NMR; these results are compared to other published NMR studies of the TAR hairpin. Assignments of all nonexchangeable protons and of all the stem-exchangeable protons have been made, as well as all phosphorus and many carbon resonances. Large J1'2' and J3'4' proton-proton coupling in the C5, G8, and G9 sugars indicate an equilibrium between C2'- and C3'-endo forms; these data show a dynamic loop structure. We see three broad imino resonances that have not been reported before; these resonances are in the right region for unbonded loop imino protons. These peaks suggest the protons are protected from fast exchange with the solvent by the structure of the hairpin loop. Simulated annealing and molecular dynamics with 148 distance constraints, 11 hydrogen bonds, and 84 torsion angle constraints showed a wide variety of structures. Certain trends are evident, such as continuation of the A-form helix on the 3' side of the hairpin loop. The ensemble of calculated structures agree with most chemical modification data.

Selective isotopic enrichment of synthetic RNA: application to the HIV-1 TAR element.

The introduction of isotopically enriched nucleotides into NMR quantities of a synthetic 29-mer RNA derived from the HIV-1 TAR element is described. RNA enriched in 13C and/or 15N is produced by a procedure which involves isolation of whole cellular RNA from Escherichia coli, nucleolysis, separation of mononucleotides, chemical or enzymatic pyrophosphorylation, and in vitro transcription by T7 RNA polymerase. Spectral characteristics of each residue type are examined in isolation. 13C chemical shifts provide an alternative method to determine ribose puckers for larger RNAs. Nonprotonated sites such as purine N7 groups can now be monitored through the use of multiple-bond 1H-15N coupling. When applied conservatively, coordinate analysis of chemical shift values should prove valuable for NMR studies of RNA structure and recognition. 1H, 13C, and 15N chemical shift data suggest that TAR residue A35 has an unusual local environment, consistent with extrusion of its base from the terminal loop.