Identification by phage display selection of a short peptide able to inhibit only the strand transfer reaction catalyzed by human immunodeficiency virus type 1 integrase.

Human immunodeficiency virus type 1 integrase catalyzes the integration of proviral DNA into the infected cell genome, so it is an important potential target for antiviral drug design. In an attempt to search for peptides that specifically interact with integrase (IN) and inhibit its function, we used an in vitro selection procedure, the phage display technique. A phage display library of random heptapeptides was used to screen for potential peptide ligands of HIV-1 IN. Several phage clones were identified that specifically bound IN. Two of the selected peptides (FHNHGKQ and HLEHLLF) exhibited a high affinity for IN and were chemically synthesized. High affinity was confirmed by a displacement assay which showed that these two synthetic peptides were able to compete with the phages expressing the corresponding peptide. These agents were assayed on the in vitro IN activities. While none of them inhibited the 3'-processing reaction, the FHNHGKQ peptide was found to be an inhibitor of the strand transfer reaction. Despite its high affinity for IN, the HLEHLLF peptide selected and assayed under the same conditions was unable to inhibit this reaction. We showed that the FHNHGKQ peptide inhibits specifically the strand transfer activity by competing with the target DNA for binding to IN. These IN-binding agents could be used as a base for developing new anti-integrase compounds as well as for structural studies of the still unknown three-dimensional structure of the entire integrase molecule.

The lethal phenotype observed after HIV-1 integrase expression in yeast cells is related to DNA repair and recombination events.

Human immunodeficiency virus type 1 (HIV-1) integrase (IN) catalyzes the insertion of the viral genome into the host cell DNA, an essential reaction during the retroviral cycle. We described previously that expression of HIV-1 IN in some yeast strains may lead to the emergence of a lethal phenotype which was not observed when the catalytically crucial residues D, D, (35)E were mutated. The lethal effect in yeast seems to be related to the mutagenic effect of the recombinant HIV-1 IN, most probably via the non-sequence-specific endonucleolytic activity carried by this enzyme. This non-sequence-specific endonuclease activity was further characterized. Although the enzyme was active on DNA substrates devoid of viral long terminal repeat (LTR) sequences, the presence of LTR regions stimulated significantly this activity. Genetic experiments were designed to show that both the mutagenic effect and the level of recombination events were affected in cells expressing the active retroviral enzyme, while expression of the mutated inactive IN D116A has no significant effect. A close interaction was demonstrated between integrase activity and in vivo/in vitro recombination process, suggesting that retroviral integration and recombination mechanism are linked in the infected cell. Our results show that the yeast system is a powerful cellular model to study the non-sequence-specific endonucleolytic activity of IN. Its characterization is essential since this activity might represent a very important step in the retroviral infectious cycle and would provide further insights into the function of IN. Indeed, effectors of this activity should be sought as potential antiviral agents since stimulation of this enzymatic activity would induce the destruction of early synthesized proviral DNA.

A novel short peptide is a specific inhibitor of the human immunodeficiency virus type 1 integrase.

The retroviral encoded protein integrase (IN) is required for the insertion of the human immunodeficiency virus type 1 (HIV-1) proviral DNA into the host genome. In spite of the crucial role played by IN in the retroviral life cycle, which makes this enzyme an attractive target for the development of new anti-AIDS agents, very few inhibitors have been described and none seems to have a potential use in anti-HIV therapy. To obtain potent and specific IN inhibitors, we used the two-hybrid system to isolate short peptides. Using HIV-1 IN as a bait and a yeast genomic library as the source of inhibitory peptides (prey), we isolated a 33-mer peptide (I33) that bound tightly to the enzyme. I33 inhibited both in vitro IN activities, i.e. 3' end processing and strand transfer. Further analysis led us to select a shorter peptide, EBR28, corresponding to the N-terminal region of I33. Truncated variants showed that EBR28 interacted with the catalytic domain of IN interfering with the binding of the DNA substrate. Alanine single substitution of each EBR28 residue (alanine scanning) allowed the identification of essential amino acids involved in the inhibition. The EBR28 NMR structure shows that this peptide adopts an alpha-helical conformation with amphipathic properties. Additionally, EBR28 showed a significant antiviral effect when assayed on HIV-1 infected human cells. Thus, this potentially important short lead peptide may not only be helpful to design new anti-HIV agents, but also could prove very useful in further studies of the structural and functional characteristics of HIV-1 IN.

HIV-1 integrase interacts with yeast microtubule-associated proteins.

The human immunodeficiency virus type 1 (HIV-1) integrase (IN) mediates the insertion of viral DNA into the human genome. In addition to IN, cellular and viral proteins are associated to proviral DNA in the so-called preintegration complex (PIC). We previously reported that the expression of HIV-1 IN in yeast leads to the emergence of a lethal phenotype. This effect may be linked to the IN activity on infected human cells where integration requires the cleavage of genomic DNA. To isolate and characterize potential cellular partners of HIV-1 IN, we used it as a bait in a two-hybrid system with a yeast genomic library. IN interacted with proteins belonging to the microtubule network, or involved in the protein synthesis apparatus. We focused our interest on one of the selected inserts, L2, which corresponds to the C-end half of the yeast STU2p, a microtubule-associated protein (MAP). STU2p is an essential component of the yeast spindle pole body (SPB), which is able to bind microtubules in vitro. After expressing and purifying L2 as a recombinant protein, we showed its binding to IN by ELISA immunodetection. L2 was also able to inhibit IN activity in vitro. In addition, the effect of L2 was tested using the "lethal yeast phenotype". The coexpression of IN and the L2 peptide abolished the lethal phenotype, thus showing important in vivo interactions between IN and L2. The identification of components of the microtubule network associated with IN suggest a role of this complex in the transport of HIV-1 IN present in the PIC to the nucleus, as already described for other human viruses.

Inhibitors of HIV-1 reverse transcriptase and integrase: classical and emerging therapeutical approaches.

The rapid spread of the AIDS epidemic has stimulated the search for new agents able to arrest the replication of the causative virus, HIV. The best strategy for AIDS treatment involves a combination therapy using inhibitors of reverse transcriptase and protease. However, the emergence of HIV-1 strains resistant to these drugs and their cytotoxicity requires the synthesis and the biochemical and cellular characterization of new antiviral drugs, as well as the development of newer strategies and viral targets. In addition to reverse transcriptase and protease, other retroviral enzymes acting in the replicative cycle of HIV-1 are potential targets for chemotherapeutic intervention. Like all retroviruses, HIV-1 requires the integration of the proviral double-stranded DNA, arising from the reverse transcription step, into the host chromosome for its efficient replication, maintenance of a stably infected state and productive infection. DNA integration is carried out by integrase so this enzyme represents a key area in developing new anti-retroviral therapy. Another novel enzymatic target concerns the RNase H activity associated with the retroviral reverse transcriptase, since a functional RNase H is essential for retroviral replication. Inhibitors against HIV-1 integrase and RNase H having potential therapeutical propeties have not yet been described. We focus this review on the properties of inhibitors of reverse transcriptase and integrase. Some of these antiviral agents have been known for several years while others are emerging as new promising strategies based on the use of oligonucleotides with special emphasis on the SELEX approach, peptides and retrovirucides.