Interfacial peptide inhibitors of HIV-1 integrase activity and dimerization

Peptides derived from the interfacial region of dimeric HIV-1 integrase were evaluated as inhibitors of integrase's 3'-endonuclease activity. Three peptides were found to be moderately potent inhibitors with IC(50) values in the low micromolar range. The mode of inhibition was probed through protein crosslinking experiments. Active interfacial peptides were found to inhibit crosslinking of the dimeric form of integrase. Interfacial peptides that were poor inhibitors had no effect on integrase crosslinking.     

Discovery of small molecule HIV-1 integrase dimerization inhibitors

Human immunodeficiency virus-1 integrase (HIV-1 IN) inserts the viral DNA into host cell chromatin in a multistep process. This enzyme exists in equilibrium between monomeric, dimeric, tetrameric and high order oligomeric states. However, monomers of IN are not capable of supporting its catalytic functions and the active form has been shown to be at least a dimer. As a consequence, the development of inhibitors targeting IN dimerization constitutes a promising novel antiviral strategy. In this work, we successfully combined different computational techniques in order to identify small molecule inhibitors of IN dimerization. Additionally, a novel AlphaScreen-based IN dimerization assay was used to evaluate the inhibitory activities of the selected compounds. To the best of our knowledge, this study represents the first successful virtual screening and evaluation of small molecule HIV-1 IN dimerization inhibitors, which may serve as attractive hit compounds for the development of novel anti-HIV.     

HIV-1 integrase crosslinked oligomers are active in vitro

The oligomeric state of active human immunodeficiency virus type 1 (HIV-1) integrase (IN) has not been clearly elucidated. We analyzed the activity of the different purified oligomeric forms of recombinant IN obtained after stabilization by platinum crosslinking. The crosslinked tetramer isolated by gel chromatography was able to catalyze the full-site integration of the two viral LTR ends into a target DNA in vitro, whereas the isolated dimeric form of the enzyme was involved in the processing and integration of only one viral end. Accurate concerted integration by IN tetramers was confirmed by cloning and sequencing. Kinetic studies of DNA-integrase complexes led us to propose a model explaining the formation of an active complex. Our data suggest that the tetrameric IN bound to the viral DNA ends is the minimal complex involved in the concerted integration of both LTRs and should be the oligomeric form targeted by future inhibitors.     

Design and synthesis of dimeric HIV-1 integrase inhibitory peptides

Dimers of known HIV-1 integrase inhibitory hexapeptide H-His-Cys-Lys-Phe-Trp-Trp-NH(2) containing different lengths of cross linkers in the place of cysteine residue, were designed, and synthesized. The inhibitory potency of these dimeric peptides is consistently higher than the lead hexapeptide. The dimeric peptide with djenkolic acid linker exhibited IC(50) values of 5.3 and 6.5 microM, for 3'-end processing and strand transfer, respectively.     

HIV-1 integrase can process a 3'-end crosslinked substrate.

Integrase of the human immunodeficiency virus type-1 (HIV-1) recognizes specific sequences located in the U3 and U5 regions at the ends of viral DNA. We synthesized DNA duplexes mimicking the U5 region and containing either 2'-aminonucleosides or non-nucleoside 1,3-propanediol insertions at the third and terminal positions and studied their interactions with HIV-1 integrase. Both modifications introduced a local structural distortion in the DNA double helix. Replacement of the terminal nucleosides by corresponding 2'-aminonucleosides had no significant effect on integrase activity. We used an integrase substrate bearing terminal 2'-aminonucleosides in both strands to synthesize a duplex with cross-linked strands. This duplex was then used to determine whether terminal base pair disruption is an obligatory step of retroviral DNA 3'-processing. Processing of the cross-linked analog of the integrase substrate yielded a product of the same length as 3'-processing of the wild-type substrate but the reaction efficiency was lower. Replacement of the third adenosine in the processed strand by a corresponding 2'-aminonucleoside did not affect integrase activity, whereas, its replacement by 1,3-propanediol completely inhibited 3'-processing. Both modifications of the complementary thymidine in the nonprocessed strand increased the initial rate of 3'-processing. The same effect was observed when both nucleosides, at the third position, were replaced by corresponding 2'-aminonucleosides. This indicates that the local duplex distortion facilitated the cleavage of the phosphodiester bond. Thus, a localized destabilization of the third A-T base pair is necessary for efficient 3'-processing, whereas 3'-end-fraying is important but not absolutely required.     

Rationally designed interfacial peptides are efficient in vitro inhibitors of HIV-1 capsid assembly with antiviral activity

Virus capsid assembly constitutes an attractive target for the development of antiviral therapies; a few experimental inhibitors of this process for HIV-1 and other viruses have been identified by screening compounds or by selection from chemical libraries. As a different, novel approach we have undertaken the rational design of peptides that could act as competitive assembly inhibitors by mimicking capsid structural elements involved in intersubunit interfaces. Several discrete interfaces involved in formation of the mature HIV-1 capsid through polymerization of the capsid protein CA were targeted. We had previously designed a peptide, CAC1, that represents CA helix 9 (a major part of the dimerization interface) and binds the CA C-terminal domain in solution. Here we have mapped the binding site of CAC1, and shown that it substantially overlaps with the CA dimerization interface. We have also rationally modified CAC1 to increase its solubility and CA-binding affinity, and designed four additional peptides that represent CA helical segments involved in other CA interfaces. We found that peptides CAC1, its derivative CAC1M, and H8 (representing CA helix 8) were able to efficiently inhibit the in vitro assembly of the mature HIV-1 capsid. Cocktails of several peptides, including CAC1 or CAC1M plus H8 or CAI (a previously discovered inhibitor of CA polymerization), or CAC1M+H8+CAI, also abolished capsid assembly, even when every peptide was used at lower, sub-inhibitory doses. To provide a preliminary proof that these designed capsid assembly inhibitors could eventually serve as lead compounds for development of anti-HIV-1 agents, they were transported into cultured cells using a cell-penetrating peptide, and tested for antiviral activity. Peptide cocktails that drastically inhibited capsid assembly in vitro were also able to efficiently inhibit HIV-1 infection ex vivo. This study validates a novel, entirely rational approach for the design of capsid assembly interfacial inhibitors that show antiviral activity.     

Development of an AlphaScreen-based HIV-1 integrase dimerization assay for discovery of novel allosteric inhibitors

In recent years, HIV-1 integrase (IN) has become an established target in the field of antiretroviral drug discovery. However, its sole clinically approved inhibitor, the integrase strand transfer inhibitor (INSTI) raltegravir, has a surprisingly low genetic barrier for resistance. Furthermore, the only two other integrase inhibitors currently in advanced clinical trials, elvitegravir and dolutegravir, share its mechanism of action and certain resistance pathways. To maintain a range of treatment options, drug discovery efforts are now turning toward allosteric IN inhibitors, which should be devoid of cross-resistance with INSTIs. As IN requires a precise and dynamic equilibrium between several oligomeric species for its activities, the modulation of this equilibrium presents an interesting allosteric target. We report on the development, characterization, and validation of an AlphaScreen-based assay for high-throughput screening for modulators of HIV-1 IN dimerization. Compounds identified as hits in this assay proved to act as allosteric IN inhibitors. Additionally, the assay offers a flexible platform to study IN dimerization.     

Modulation of HIV-1 integrase activity by single-stranded oligonucleotides and their conjugates with eosin

Integration of the DNA copy of the genomic RNA into an infected cell genome is one of the key steps of the replication cycle of all retroviruses. It is catalyzed by the viral enzyme, integrase. We have shown that conjugates of short single-stranded oligonucleotides with eosin efficiently inhibit the catalytic activity of the HIV-1 integrase. In this article, we have found that the dependence of the integrase catalytic activity on the concentration of oligonucleotides has a bell-shaped pattern. The modulation of HIV-1 integrase activity correlated with the oligonucleotide length and was not associated with specific sequences. Moreover, a similar mode of the oligonucleotide action was found for integrase from the prototype foamy virus. This dual effect of the oligonucleotide and their conjugates with eosin might be explained by their binding with retroviral integrase in two different sites; the oligodeoxynucleotide binding in the first site results in integrase activation, whereas interactions with another one lead to inhibition of the enzyme activity. Eosin coupling to oligonucleotides did not change the mode of their action but enhanced their affinity to both binding sites. The affinity increase was found to be much more important for the site responsible for the integrase inhibition, thus explaining the high inhibitory potency of oligonucleotide-eosin conjugates.     

Inhibition of HIV-1 virion production by a transdominant mutant of integrase interactor 1

Integase interactor 1 (INI1), also known as hSNF5, is a protein that interacts with HIV-1 integrase. We report here that a cytoplasmically localized fragment of INI1 (S6; aa183-294) containing the minimal integrase-interaction domain potently inhibits HIV-1 particle production and replication. Mutations in S6 or integrase that disrupt integrase-INI1 interaction abrogated the inhibitory effect. An integrase-deficient HIV-1 transcomplemented with integrase fused to Vpr was not affected by S6. INI1 was specifically incorporated into virions and was required for efficient HIV-1 particle production. These results indicate that INI1 is required for late events in the viral life cycle, and that ectopic expression of S6 inhibits HIV-1 replication in a transdominant manner via its specific interaction with integrase within the context of Gag-Pol, providing a novel strategy to control HIV-1 replication.     

Inhibition of the strand transfer step of HIV-1 integrase by non-natural dinucleotides

New, non-natural dinucleotide 5'-monophosphates, with a surrogate isonucleoside component of l-related stereochemistry at the 'terminal' position, have been synthesized. Structures of 2a-c were confirmed by multinuclear NMR spectra ((1)H, (13)C, (31)P, COSY), UV hypochromicity and FAB HRMS data. These compounds are totally resistant to cleavage by 3'- and 5'-exonucleases. The dinucleotides showed remarkable selectivity for inhibition of the strand transfer step of HIV-1 integrase. To the best of our knowledge, these compounds represent only the second example of selective strand transfer inhibitors of HIV integrase.     

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.     

Linker-modified quinoline derivatives targeting HIV-1 integrase: synthesis and biological activity

A novel series of HIV-1 integrase inhibitors was synthesized and tested in both in vitro and ex vivo assays. These inhibitors are featured by the presence of a quinoline subunit and an ancillary aromatic ring linked by functionalized spacers such as amide, hydrazide, urea and 1-hydroxyprop-1-en-3-one moiety. Amide derivatives are the most promising ones and could serve as leads for further developments.     

Inhibition of HIV-1 replication by cell-penetrating peptides binding Rev

New therapeutic agents able to block HIV-1 replication are eagerly sought after to increase the possibilities of treatment of resistant viral strains. In this report, we describe a rational strategy to identify small peptide sequences owning the dual property of penetrating within lymphocytes and of binding to a protein target. Such sequences were identified for two important HIV-1 regulatory proteins, Tat and Rev. Their association to a stabilizing domain consisting of human small ubiquitin-related modifier-1 (SUMO-1) allowed the generation of small proteins named SUMO-1 heptapeptide protein transduction domain for binding Tat (SHPT) and SUMO-1 heptapeptide protein transduction domain for binding Rev (SHPR), which are stable and efficiently penetrate within primary lymphocytes. Analysis of the antiviral activity of these proteins showed that one SHPR is active in both primary lymphocytes and macrophages, whereas one SHPT is active only in the latter cells. These proteins may represent prototypes of new therapeutic agents targeting the crucial functions exerted by both viral regulatory factors.     

Probing the role of interfacial residues in a dimerization inhibitor of HIV-1 protease.

The importance of each side chain of a cross-linked interfacial peptide inhibitor of HIV-1 protease was evaluated using an alanine scanning approach. Whereas the parent inhibitor has an IC50 value of 350 nM, values for the mutations reported here range from 280-9200 nM. The relative importance or each residue was thus assigned and correlated to the solvent accessible surface area (SASA) exposed upon mutation.     

Chemical and enzymatic modifications of integric acid and HIV-1 integrase inhibitory activity

Integric acid (1), an acyl eremophilane sesquiterpenoid, was identified as an inhibitor of HIV-1 integrase, the enzyme responsible for provirus entry into the host cell nucleus and integration in to the host genome. Chemical and enzymatic modification of integric acid led to the preparation of several selective chemical derivatives of integric acid. Preparation, HIV-1 inhibitory activity, and the structure-activity relationship against coupled and strand transfer assays are described. It appears that most of the groups present in the natural product are required for inhibition of HIV-1 integrase strand transfer activity. In contrast, inhibition of 3' processing activity is less stringent suggesting distinct SAR for the two integrase reactions.     

Evaluation of the activity of HIV-1 integrase over-expressed in eukaryotic cells

Since the integration of viral DNA in the host genome is an essential step in the replication cycle of HIV-1, an active search for inhibitors of the integration step is ongoing. Our laboratory has been working on the development of a cellular integration system. Such a system would be helpful in the study of the HIV-1 integration process and, eventually, could be used in the search for new inhibitors that selectively interfere with HIV integration. We have previously selected stable cell lines (293T-INS) that constitutively express high levels of HIV-1 integrase (IN) from a synthetic gene [FASEB J. 14 (2000) 1389]. We have now constructed linear DNA substrates containing the terminal HIV LTR sequences (so called 'mini-HIV') and EGFP as reporter gene to evaluate whether IN can improve the integration of transfected linear DNA. After electroporation of this mini-HIV we observed a 2- to 3-fold increase in EGFP expression in IN expressing cell lines relative to control cells. The increase in EGFP expression was still evident after passaging of the cells. The effect was observed with linear DNA but not with circular DNA, thus excluding an effect on DNA uptake. The increase was the highest in the 293T-INS(D64V) cell line due to an increase in the amount of total mini-HIV DNA and 2-LTR circles as quantified by Q-PCR. Our data suggest that IN over-expressed in our cell lines interacts with the incoming DNA, protects it from nuclease degradation but does not catalyze the integration as such.