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.     

Inhibition of human immunodeficiency virus type 1 integrase by the Fab fragment of a specific monoclonal antibody suggests that different multimerization states are required for different enzymatic functions.

We have characterized a murine monoclonal antibody (MAb 35), which was raised against human immunodeficiency virus type 1 (HIV-1) integration protein (IN), and the corresponding Fab 35. Although MAb 35 does not inhibit HIV-1 IN, Fab 35 does. MAb 35 (and Fab 35) binds to an epitope in the C-terminal region of HIV-1 IN. Fab 35 inhibits 3'-end processing, strand transfer, and disintegration; however, DNA binding is not affected. The available data suggest that Fab 35 inhibits enzymatic activities of IN by interfering with the ability of IN to form multimers that are enzymatically active. This implies that the C-terminal region of HIV-1 IN participates in interactions that are essential for the multimerization of IN. Titration of the various IN-mediated enzymatic activities suggests that different degrees of multimerization are required for different activities of HIV-1 IN.     

Interaction between HIV-1 Rev and integrase proteins: a basis for the development of anti-HIV peptides

Human immunodeficiency virus 1 (HIV-1) Rev and integrase (IN) proteins are required within the nuclei of infected cells in the late and early phases of the viral replication cycle, respectively. Here we show using various biochemical methods, that these two proteins interact with each other in vitro and in vivo. Peptide mapping and fluorescence anisotropy showed that IN binds residues 1-30 and 49-74 of Rev. Following this observation, we identified two short Rev-derived peptides that inhibit the 3'-end processing and strand-transfer enzymatic activities of IN in vitro. The peptides bound IN in vitro, penetrated into cultured cells, and significantly inhibited HIV-1 in multinuclear activation of a galactosidase indicator (MAGI) and lymphoid cultured cells. Real time PCR analysis revealed that the inhibition of HIV-1 multiplication is due to inhibition of the catalytic activity of the viral IN. The present work describes novel anti-HIV-1 lead peptides that inhibit viral replication in cultured cells by blocking DNA integration in vivo.     

Study on the molecular mechanism of inhibiting HIV-1 integrase by EBR28 peptide via molecular modeling approach

Human immunodeficiency virus type 1 (HIV-1) integrase (IN) is an essential enzyme in the HIV-1 lifecycle which aids the integration of viral DNA into the host chromosome. Recently synthesized 12-mer peptide EBR28, which can strongly bind to IN, is one of the most potential small peptide leading compounds inhibiting IN binding with viral DNA. However, the binding mode between EBR28 peptide with HIV-1 IN and the inhibition mechanism remain uncertain. In this paper, the binding modes of EBR28 with HIV-1 IN monomer core domain (IN(1)) and dimmer core domain (IN(2)) were investigated by using molecular docking and molecular dynamics (MD) simulation methods. The results indicated that EBR28 bound to the interfaces of the IN(1) and IN(2) systems mainly through the hydrophobic interactions with the beta3, alpha1 and alpha5 regions of the proteins. The binding free energies for IN(1) with a series of EBR28 mutated peptides were calculated with the MM/GBSA model, and the correlation between the calculated and experimental binding free energies is very good (r=0.88). Thus, the validity of the binding mode of IN(1) with EBR28 was confirmed. Based on the binding modes, the inhibition mechanism of EBR28 was explored by analyzing the essential dynamics (ED), energy decomposition and the mobility of EBR28 in the two docked complexes. The proposed inhibition mechanism is represented that EBR28 binds to the interface of IN(1) to form the IN(1)_EBR28 complex and preventes the formation of IN dimmer, finally leads to the partial loss of binding potency for IN with viral DNA. All of the above simulation results agree well with experimental data, which provide us with some helpful information for designing anti-HIV small peptide drugs.     

Peptide inhibitors of HIV-1 integrase: From mechanistic studies to improved lead compounds

The HIV-1 integrase enzyme (IN) catalyzes integration of viral DNA into the host genome. We previously developed peptides that inhibit IN in vitro and HIV-1 replication in cells. Here we present the design, synthesis and evaluation of several derivatives of one of these inhibitory peptides, the 20-mer IN1. The peptide corresponding to the N-terminal half of IN1 (IN1 1–10) was easier to synthesize and much more soluble than the 20-mer IN1. IN1 1–10 bound IN with improved affinity and inhibited IN activity as well as HIV replication and integration in infected cells. While IN1 bound the IN tetramer, its shorter derivatives bound dimeric IN. Mapping the peptide binding sites in IN provided a model that explains this difference. We conclude that IN1 1–10 is an improved lead compound for further development of IN inhibitors.     

Correlation between shiftide activity and HIV-1 integrase inhibition by a peptide selected from a combinatorial library

The human immunodeficiency virus type 1 (HIV-1) integrase (IN) protein is an emerging target for the development of anti-HIV drugs. We recently described a new approach for inhibiting IN by “shiftides”—peptides that inhibit the protein by shifting its oligomerization equilibrium from the active dimer to the inactive tetramer. In this study, we used the yeast two-hybrid system with the HIV-1 IN as a bait and a combinatorial peptide aptamer library as a prey to select peptides of 20 amino acids that specifically bind IN. Five non-homologous peptides, designated as IN-1 to IN-5, were selected. ELISA studies confirmed that IN binds the free peptides. All the five peptides interact with IN with comparable affinity (K_d≈10 μM), as was revealed by fluorescence anisotropy studies. Only one peptide, IN-1, inhibited the enzymatic activity of IN in vitro and the HIV-1 replication in cultured cells. In correlation, fluorescence anisotropy binding experiments revealed that of the five peptides, only the inhibitory IN-1 inhibited the DNA binding of IN. Analytical gel filtration experiments revealed that only the IN-1 and not the four other peptides shifted the oligomerization equilibrium of IN towards the tetramer. Thus, the results show a distinct correlation between the ability of the selected peptides to inhibit IN activity and that to shift its oligomerization equilibrium.     

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.     

Inhibition of protein kinase C and anti-CD3-induced Ca2+ influx in Jurkat T cells by a synthetic peptide with sequence identity to HIV-1 gp41

We have previously shown that a synthetic peptide containing env residues 581-597 from HIV-1 inhibits lymphoproliferation of human PBMC. We have investigated the molecular mechanism(s) by which this HIV-1-derived peptide inhibits CD3-mediated signal transduction. We show that the peptide containing residues 581-597 from the HIV-1 transmembrane protein gp41 specifically inhibited the intracellular Ca2+ influx in Jurkat cells stimulated by the mAb OKT3 whereas it had no effect on the production of inositol triphosphate. In addition, the peptide inhibited protein kinase C (pkC)-mediated phosphorylation of the CD3 gamma-chain in intact cells and directly inhibited partially purified pkC. The inhibition was noncompetitive with respect to the substrates histone and ATP and independent of the regulatory domain of the enzyme. Furthermore, the peptide required internalization for inhibitory activity because no inhibition of lymphoproliferation was observed when cells were treated with peptide at 4 degrees C. Based on these results obtained with the peptide aa581-597, we postulate that the transmembrane protein gp41 of HIV-1 may inhibit pkC activity and thus block pkC-dependent immune function contributing to the immunosuppression of HIV-1-infected individuals.     

Inhibitory effect of the catalytic domain of myosin light chain kinase on actin-myosin interaction: insight into the mode of inhibition.

The catalytic domain of myosin light chain kinase (MLCK) not only exerts kinase activity to phosphorylate the 20 kDa light chain but also inhibits the actin-myosin interaction. The site of action of this novel role of the domain has been suggested to be myosin [Okagaki et al. (1999) J. Biochem. 125, 619-626]. In this study, we have analyzed the amino acid sequences of MLCK and myosin that are involved in the inhibition. The ATP-binding peptide of Gly526-Lys548 of chicken gizzard MLCK exerted the inhibitory effect on the movement of actin filaments on a myosin-coated glass surface. However, the peptide that neighbors the sequence failed to inhibit the movement. The inhibition of the ATP-binding peptide was confirmed by measuring ATPase activities of the myosin. The inhibition by parent MLCK of the movement was relieved by the 20 kDa light chain, but not by the 17 kDa myosin light chain. The peptide of the 20 kDa light chain sequence of Ser1-Glu29 also relieved the inhibition. Thus, the interaction of the ATP-binding sequence with the 20 kDa light chain sequence should cause the inhibition of the actin-myosin interaction. Concerning the regulation of the inhibition, calmodulin relieved the inhibitory effect of MLCK on the movement of actin filaments. The calmodulin-binding peptide (Ala796 Ser815) prevented the relief, suggesting the involvement of this sequence. Thus, the mode of regulation by Ca2+ and calmodulin of the novel role of the catalytic domain is similar, but not identical, to the mode of regulation of the kinase activity of the domain.     

Characterization of Mutant HIV-1 Integrase Carrying Amino Acid Changes in the Catalytic Domain

To gain insight into the importance of conserved residues in the core domain of HIV-1 IN, we performed site-directed mutagenesis of the full-length enzyme, overexpressed the mutant proteins in E. coli, purified and analyzed their 3-processing, integration and disintegration activities in vitro. Change of E152V in the DD(35)E motif abolished all detectable activities of IN. Alteration of two highly conserved residues, P145 and K156, by isoleucine, resulted in a substantial loss or completely abolished the three activities of the enzyme. Mutant P90D weakly reduced the 3-processing but severely affected the two other IN activities. Results obtained from double and triple mutations, P90D/P145I and P145I/F185K/C280S, clearly suggest a crucial role of P145 in the catalytic function of IN, whereas the mutants V150E, L158F and L172M had no detectable effect on any of the IN activities. Taken together, these results allowed us to conclude that all the conserved amino acids in the core domain of IN are not equally important for catalytic functions: like D64, D116 and E152, our data suggest that P90, P145 and K156 are also essential for all three enzymatic activities of HIV-1 IN in vitro, whereas V150, L158 and L172 appear to be less critical.     

Identification of the catalytic and DNA-binding region of the human immunodeficiency virus type I integrase protein.

The integrase (IN) protein of the human immunodeficiency virus (HIV) is required for specific cleavage of the viral DNA termini, and subsequent integration of the viral DNA into target DNA. To identify the various domains of the IN protein we generated a series of IN deletion mutants as fusions to maltose-binding protein (MBP). The deletion mutants were tested for their ability to bind DNA, to mediate site-specific cleavage of the viral DNA ends, and to carry out integration and disintegration reactions. We found that the DNA-binding region resides between amino acids 200 and 270 of the 288-residues HIV-1 IN protein. The catalytic domain of the protein was mapped between amino acids 50 and 194. For the specific activities of IN, cleavage of the viral DNA and integration, both the DNA-binding domain and the conserved amino-terminal region of IN are required. These regions are dispensable however, for disintegration activity.     

Minimal Core Domain of HIV-1 Integrase for Biological Activity

The human immunodeficiency virus type-1 (HIV-1) integrase (IN) mediates insertion of viral DNA into human DNA, which is an essential step in the viral life cycle. In order to study minimal core domain in HIV-1 IN protein, we constructed nine deletion mutants by using PCR amplification. The constructs were expressed in Escherichia coli, and the proteins were subsequently purified and analyzed in terms of biological activity such as enzymatic and DNA-binding activities. The mutant INs with an N-terminal or C-terminal deletion showed strong disintegration activity though they failed to show endonucleolytic and strand transfer activities, indicating that the disintegration reaction does not require the fine structure of the HIV-1 IN protein. In the DNA-binding analysis using gel mobility shift assay and UV cross-linking method, it was found that both the central and C-terminal domains are essential for proper DNA-IN protein interaction although the central or C-terminal domain alone was able to be in close contact with DNA substrate. Therefore, our results suggest that the C-terminal domain act as a DNA-holding motive, which leads to proper interaction for enzymatic reaction between the IN protein and DNA.