Refolded HIV-1 tat protein protects both bulge and loop nucleotides in TAR RNA from ribonucleolytic cleavage

Substantial evidence indicates that HIV-1 trans-activation by tat protein is mediated through the TAR RNA element. This RNA forms a stem-loop structure containing a three-nucleotide bulge and a six-nucleotide loop. Previous mutagenic analysis of TAR indicates that the bulge residues and a 4 bp segment of the stem constitute, in part, the tat binding site. However, there appears to be no sequence-specific contribution of the six-base loop. We have employed a ribonuclease protection technique to explore the interaction of tat with single-stranded regions of TAR. The results indicate that tat interacts with both the bulge and loop regions of TAR. Treatment of TAR RNA with RNase A results in cleavage at U23 and U31, located in the bulge and loop regions, respectively. High concentrations (approximately 2 microM) of Escherichia coli derived tat protein, prepared by standard procedures, gave complete protection of TAR RNA from RNase A cleavage. However, under these conditions, truncated TAR derivatives in which no stem-loop structure is expected to form were also protected, indicating nonspecific binding. In order to obtain a tat preparation with enhanced specificity toward TAR RNA, methods were developed for refolding the recombinant protein. This treatment enhanced the affinity of tat for TAR by approximately 30-fold [Kd(apparent) less than 25 nM] and markedly increased its specificity for the TAR. Again, tat protected TAR RNA from RNase A cleavage at both U23 and U31. Protection was also observed with RNase T1 which cleaves TAR RNA at three G residues in the six-base loop.(ABSTRACT TRUNCATED AT 250 WORDS)     

Substrate structure requirements of the Pac1 ribonuclease from Schizosaccharmyces pombe.

The Pac1 ribonuclease of Schizosaccharomyces pombe is a member of the RNase III family of double-strand-specific ribonucleases. To examine RNA structural features required for efficient cleavage by the Pac1 RNase, we tested a variety of double-stranded and hairpin RNAs as substrates for the enzyme. The Pac1 RNase required substrates that have a minimal helix length of about 20 base pairs. The enzyme cut both strands of the helix at sites separated by two base pairs. However, Pac1 was also able to make a single-stranded cleavage within an internal bulge of an authentic Escherichia coli substrate at the same site chosen by RNase III. Pac1 efficiently degraded the structurally complex adenovirus VA RNA(I), but was inactive against the short HIV-1 TAR RNA hairpin. These results indicate that the Pac1 RNase prefers straight, perfect helices, but it can tolerate internal bulges that do not distort the helix severely. Like its homologue from Saccharomyces cerevisiae, the Pac1 RNase cleaved at two in vivo RNA processing sites in a hairpin structure in the 3' external transcribed spacer of the S. pombe pre-rRNA, suggesting a role for the enzyme in rRNA maturation.     

Lentiviral-mediated delivery of combined HIV-1 decoy TAR and Vif siRNA as a single RNA molecule that cleaves to inhibit HIV-1 in transduced cells

RNA interference (RNAi) silences gene expression via short interfering 21-23 mer double-stranded RNA (siRNA) segments that guide cognate mRNA degradation in a sequence-specific manner. On the other hand, HIV-1 decoy TAR RNA are known to competitively interact with the HIV-1 Tat protein, to downregulate the enhanced gene expression from the long terminal repeat (LTR) promoters. Here we report that a novel expression construct, encoding both HIV-1 decoy TAR and Vif siRNA, as a single RNA substrate, was expressed under the control of the human U6 promoter, and later the TAR and siRNA were cleaved into their respective separate RNA by the endogenous RNase III-like enzyme. Each of the cleaved HIV-1 anti-genes then synergistically contributed toward enhancing the inhibition efficacy (>80%) of HIV-1 replication in transduced Jurkat cells. These results suggest that targeting HIV-1 mRNA with simultaneously expressed intracellular decoy TAR and Vif-siRNA could lead to an effective gene therapy strategy for the control and management of HIV-AIDS.     

LENTIVIRAL-MEDIATED DELIVERY OF COMBINED HIV-1 DECOY TAR AND Vif siRNA AS A SINGLE 1RNA MOLECULE THAT CLEAVES TO INHIBIT HIV-1 IN TRANSDUCED CELLS

RNA interference (RNA_i) silences gene expression via short interfering 21–23 mer double-stranded RNA (siRNA) segments that guide cognate mRNA degradation in a sequence-specific manner. On the other hand, HIV-1 decoy TAR RNA are known to competitively interact with the HIV-1 Tat protein, to downregulate the enhanced gene expression from the long terminal repeat (LTR) promoters. Here we report that a novel expression construct, encoding both HIV-1 decoy TAR and Vif siRNA, as a single RNA substrate, was expressed under the control of the human U6 promoter, and later the TAR and siRNA were cleaved into their respective separate RNA by the endogenous RNase III-like enzyme. Each of the cleaved HIV-1 anti-genes then synergistically contributed toward enhancing the inhibition efficacy (> 80%) of HIV-1 replication in transduced Jurkat cells. These results suggest that targeting HIV-1 mRNA with simultaneously expressed intracellular decoy TAR and Vif-siRNA could lead to an effective gene therapy strategy for the control and management of HIV-AIDS.     

Molecular basis of HIV-1 TAR RNA specific recognition by an acridine tat-antagonist.

We investigated the interaction of a highly potent acridine-based tat-antagonist with the TAR RNA of HIV-1. The wild type TAR RNA and three mutants with U-->C23, G x C-->C x G26-39 or G x C-->A x U26-39 substitutions were used as substrates to study the molecular basis of drug-TAR RNA complex formation. Melting temperature and RNase protection experiments reveal that the G x C26-39 pair is a critical element for specific major groove recognition of TAR at the pyrimidine bulge. The results provide a rational basis for future design of optimized tat/TAR inhibitors.     

TAR loop-dependent human immunodeficiency virus trans activation requires factors encoded on human chromosome 12.

The trans-activator response region (TAR) RNA in the human immunodeficiency virus type 1 (HIV-1) and HIV-2 long terminal repeat forms stem-loop secondary structures in which the loop sequence is essential for trans activation. We investigated how the HIV trans-activation mechanism encoded on human chromosome 12 relates to the TAR RNA loop-dependent pathway. DNA transfection experiments showed that trans activation in human-hamster hybrid cells with the single human chromosome 12 and human T-cell lines was highly dependent on the native sequences of the HIV-1 TAR loop and the HIV-2 5' TAR loop. In nonhuman cell lines or hybrid cells without chromosome 12 that supported trans activation, the cellular mechanism was independent of the HIV-1 TAR loop and the response to mutations in the HIV-2 TAR loops differed from that found in human T-cell lines and human-hamster hybrid cells with chromosome 12. Our results suggest that the human chromosome 12 mechanism interacts directly with the TAR RNA loop or indirectly by regulating TAR RNA-binding proteins.