Inhibition of replication of fresh HIV type 1 patient isolates by a polypurine tract-specific self-complementary oligodeoxynucleotide.

A previously described self-complementary oligodeoxynucleotide termed triplex-forming oligodeoxynucleotide (TFO A), 54 bases in length, designed against the polypurine tract of HIV-1 RNA, inhibited viral replication at a 1 to 3 microM concentration in acutely infected cells, whereas antisense and scrambled sequence oligodeoxynucleotides were ineffective. Three HIV-1 viral isolates from patients of clinical categories A1, B, and C3 were transmitted to peripheral blood mononuclear cells and tested for production of p24 antigen and syncytium formation in the absence and in the presence of either TFO A or a control oligodeoxynucleotide of randomized sequence. No p24 antigen or syncytia were detected for up to 30 days when TFO A was added to the cells. Viability of the cells was found not to be affected by the drugs compared to controls within 2 weeks. Analysis of viral DNA synthesis by PCR for the LTR and gag gene indicated no DNA signal, suggesting that TFO A affects viral replication before formation of a DNA provirus. Measurements of the stability of TFO A indicate a half-life of about 2 hr. A two-dimensional computer fold analysis of TFO A suggested a self-complementary hairpin-loop configuration with GC-rich stems and single-stranded 5' and 3' ends. Since intracellular triplex formation may not be an efficient process, the observed inhibitory effect may be due to a direct inhibition of the RT and RNase H enzyme activities by the oligodeoxynucleotide. However, a triple-helix effect on the incoming RNA may play a role as well.

Inhibition of HIV-1 reverse transcription by triple-helix forming oligonucleotides with viral RNA.

Reverse transcription of retroviral RNA into double-stranded DNA is catalyzed by reverse transcriptase (RT). A highly conserved polypurine tract (PPT) on the viral RNA serves as primer for plus-strand DNA synthesis and is a possible target for triple-helix formation. Triple-helix formation during reverse transcription involves either single-stranded RNA or an RNA.DNA hybrid. The effect of triple-helix formation on reverse transcription has been analyzed here in vitro using a three-strand-system consisting of an RNA.DNA hybrid and triplex-forming oligonucleotides (TFOs) consisting either of DNA or RNA. Three strand triple-helices inhibit RNase H cleavage of the PPT-RNA.DNA hybrid and initiation of plus-strand DNA synthesis in vitro. Triple-helix formation on a single-stranded RNA target has also been tested in a two-strand-system with TFOs comprising Watson-Crick and Hoogsteen base-pairing sequences, both targeted to the PPT-RNA, on a single strand connected by a linker (T)4. TFOs prevent RNase H cleavage of the PPT-RNA and initiation of plus-strand DNA synthesis in vitro. In cell culture experiments one TFO is an efficient inhibitor of retrovirus replication, leading to a block of p24 synthesis and inhibition of syncytia formation in newly infected cells.

Enzymatic analysis of two HIV-1 reverse transcriptase mutants with mutations in carboxyl-terminal amino acid residues conserved among retroviral ribonucleases H.

The reverse transcriptase (RT) of HIV-1 has been mutagenized within the carboxyl-terminal domain which harbors the RNase H. Two amino acids highly conserved among all 14 known RT sequences but not in the bacterial RNase H have been mutagenized resulting in the mutant proteins N494D and Q475E. They were expressed as recombinant proteins, purified, and analyzed for their in vitro properties in comparison to the p66 homodimeric wild-type and a previously described H539N mutant. The N494D mutant closely resembles the wild-type RNase H, exhibits an endonuclease activity and a processive RNase H activity, gives rise to small RNA hydrolysis products, and acts in concert with the RT. The Q475E mutant is more defective and resembles the H539N mutant, exhibits a retarded endonuclease activity and an impaired 3'-->5' processive RNA cleavage activity, gives rise to predominantly larger RNA hydrolysis products, is less processive in the presence of competitor substrate, and is defective in its ability to hydrolyze the polypurine tract and homopolymeric hybrids. Short homopolymeric stretches cause a pausing of the RT of wild-type and mutants which results in a coordinated action of the RNase H. Pausing of the RT correlates with RNase H cleavages about 20 nucleotides behind the point of synthesis. The defects of the mutant enzymes can be interpreted on the basis of the known crystallography data.

The polypurine tract, PPT, of HIV as target for antisense and triple-helix-forming oligonucleotides.

Replication of retroviral RNA into double-stranded DNA provirus involves initiation of plus-strand DNA synthesis at the polypurine tract, PPT, by the reverse transcriptase (RT). The PPT is highly conserved among the known HIV-1 retroviral isolates. It occurs twice, once within the coding region of the integrase and the other one adjacent to the 3' LTR. The data presented show that two antisense oligonucleotides, a 20-mer and a 40-mer, complementary to the PPT induce complete blocks of DNA synthesis whereas an antisense oligonucleotide outside the PPT is only slightly inhibitory. Previously polypurine sequences have been used by several groups for triplex-formation. During replication the HIV-polypurine tract, PPT, is present in a RNA-DNA hybrid. Therefore triple-helix formation consisting of RNA-DNA and a third DNA strand covering the PPT region was tested here by protection against RNase H cleavage in vitro. Incubation with a pyrimidine oligonucleotide in parallel orientation to the PPT-RNA shows some protection. GT-pyrimidine-purine mixed oligonucleotides (25-mer) led to protection against RNase H up to 50% independent of their orientation. The data suggest that triple-helix formation may have taken place with the PPT in vitro. Therefore, this highly conserved structure may prove useful in nucleic acid based anti-viral therapy with antisense or triple-helix approaches. Furthermore, the influence of HIV-1 nucleocapsid (NC) protein, NCp15, on reverse transcription is reported. The data show a two- to three-fold stimulatory effect of the NCp15 on RNA directed DNA synthesis.

Mutations of a conserved residue within HIV-1 ribonuclease H affect its exo- and endonuclease activities.

The human immunodeficiency virus 1 (HIV-1) reverse transcriptase (RT) is a protein of 66 kDa, p66, which contains two domains, an amino-terminal DNA polymerase and an RNase H at the carboxy terminus of the molecule. In order to characterize the mode of action of the RNase H, two previously described mutant enzymes were used, with substitutions in the highly conserved histidine 539, which was mutated to the neutral amino acid asparagine and to the negatively charged aspartate. The purified wild-type (wt) and mutant (mt) enzyme activities are analyzed here using RNA-DNA hybrids consisting of in vitro transcribed RNA that harbors the polypurine tract (PPT) from HIV-1 and DNA oligonucleotides complementary to the PPT or to other regions of the RNA. Analysis of the radioactively labeled RNA of these model hybrids after RNase H treatment indicates that both, wt and mt enzymes, are capable of cleaving the RNA in an endonucleolytic manner. The mt enzymes exhibit a severely reduced exonuclease activity. They are more sensitive towards salt and competition with excess of unlabeled hybrid, suggesting a reduced substrate binding affinity. DNA elongation by the RT is coupled with RNA hydrolysis by the 3'-5' exonuclease of the wt RNase H. The RNase Hmt of the mt enzymes, however, does not exhibit such processive 3'-5' exonuclease activity during DNA synthesis but gives rise to sporadic endonucleolytic cuts, whereas the RT is not affected. The endonuclease activities of the RNase H mt enzymes exhibit cleavage preferences in the absence or presence of DNA synthesis different from those of the wt enzyme. They cannot recognize specific sequences required to generate a PPT-primer and therefore cannot initiate plus-strand DNA synthesis in vitro at the 3' end of the PPT, which is essential for viral replication.