HIV-1 integrase and virus and cell DNAs: complex formation and perturbation by inhibitors of integration.

HIV-1 integrase (IN) catalyzes integration of viral DNA into cell DNA through 3'-processing of viral DNA and strand transfer reactions. To learn on binding of IN to DNAs and IN inhibition we applied spectroscopy (circular dichroism, fluorescence) in a simplified model consisting in a peptide analogue (K156) of alpha4 helix involved in recognition of viral and cell DNA; an oligonucleotide corresponding to the U5' LTR DNA end; and an inhibitor (TB11) of the diketo acid (DKA) family. Results extrapolated to IN show that: the enzyme binds viral DNA with high affinity and specificity, but cell DNA with low affinity and specificity; the affinity of TB11 for IN is high enough to impair the binding of IN to cell DNA, but not to viral DNA. This explains why TB11 is an inhibitor of strand transfer but not of 3'-processing. These results can help in the search of new IN inhibitors.

Peptide inhibitors of HIV-1 integrase dissociate the enzyme oligomers.

Integration of HIV-1 genome into host cell chromosome is mediated by viral integrase (IN). The IN catalytic core (CC, IN(50-212)) dimerizes through mutual interactions of its alpha1 and alpha5 helices. Peptides INH1 and INH5 reproducing these helix sequences strongly inhibited IN. For instance, an IC(50) of 80 nM was determined for INH5 in integration assays using wild-type IN (wtIN). In size exclusion chromatography, INH1 and INH5 perturbed the association-dissociation equilibrium of both dmIN (IN(1-288)/F185K/C280S) and CC, leading to monomers as surviving species, while in circular dichroism, binding of peptides to dmIN altered the protein conformation. Thus, enzyme deactivation, subunit dissociation, and protein unfolding are events which parallel one another. The target of INH5 in the enzyme was then identified. In fluorescence spectroscopy, C(0.5) values of 168 and 44 nM were determined for the binding affinity of INH5 to IN and CC, respectively, at 115 nM subunit concentration, while interaction of INH5 with INH1 was found stronger than interaction of INH5 with itself (23 times larger in term of dissociation constants). These results strongly suggested that the alpha1 helix is the privileged target of INH5. The latter could serve as a lead for the development of new chemotherapeutic agents against HIV-1.

Self-association and domains of interactions of an amphipathic helix peptide inhibitor of HIV-1 integrase assessed by analytical ultracentrifugation and NMR experiments in trifluoroethanol/H(2)O mixtures.

EAA26 (VESMNEELKKIIAQVRAQAEHLKTAY) is a better inhibitor of human immunodeficiency virus, type 1, integrase than its parent Lys-159, reproducing the enzyme segment 147-175 with a nonpolar-polar/charged residue periodicity defined by four helical heptads (abcdefg) prone to collapse into a coiled-coil. Circular dichroism, nuclear magnetic resonance, sedimentation equilibrium, and chemical cross-linking were used to analyze EAA26 in various trifluoroethanol/H(2)O mixtures. In pure water the helix content is weak but increases regularly up to 50-60% trifluoroethanol. In contrast the multimerization follows a bell-shaped curve with monomers in pure water, tetramers at 10% trifluoroethanol, and dimers at 40% trifluoroethanol. All suggest that interhelical interactions between apolar side chains are required for the coiled-coil formation of EAA26 and subsist at medium trifluoroethanol concentration. The N(H) temperature coefficients measured by nuclear magnetic resonance show that at low trifluoroethanol concentration the amide groups buried in the hydrophobic interior of four alpha-helix bundles are weakly accessible to trifluoroethanol and are only weakly subject to its hydrogen bond strengthening effect. The increased accessibility of trifluoroethanol to buried amide groups at higher trifluoroethanol concentration entails the reduction of the hydrophobic interactions and the conversion of helix tetramers into helix dimers, the latter displaying a smaller hydrophobic interface. The better inhibitory activity of EAA26 compared with Lys-159 could arise from its better propensity to form a helix bundle structure with the biologically important helical part of the 147-175 segment in integrase.

Conformational aspects of HIV-1 integrase inhibition by a peptide derived from the enzyme central domain and by antibodies raised against this peptide.

Monospecific antibodies were raised against a synthetic peptide K159 (SQGVVESMNKELKKIIGQVRDQAEHLKTA) reproducing the segment 147-175 of HIV-1 integrase (IN). Synthesis of substituted and truncated analogs of K159 led us to identify the functional epitope reacting with antibodies within the C-terminal portion 163-175 of K159. Conformational studies combining secondary structure predictions, CD and NMR spectroscopy together with ELISA assays, showed that the greater is the propensity of the epitope for helix formation the higher is the recognition by anti-K159. Both the antibodies and the antigenic peptide K159 exhibited inhibitory activities against IN. In contrast, neither P159, a Pro-containing analog of K159 that presents a kink around proline but with intact epitope conformation, nor the truncated analogs encompassing the epitope, were inhibitors of IN. While the activity of antibodies is restricted to recognition of the sole epitope portion, that of the antigenic K159 likely requires interactions of the peptide with the whole 147-175 segment in the protein [Sourgen F., Maroun, R.G., Frère, V., Bouziane, A., Auclair, C., Troalen, F. & Fermandjian, S. (1996) Eur. J. Biochem. 240, 765-773]. Actually, of all tested peptides only K159 was found to fulfill condition of minimal number of helical heptads to achieve the formation of a stable coiled-coil structure with the IN 147-175 segment. The binding of antibodies and of the antigenic peptide to this segment of IN hampers the binding of IN to its DNA substrates in filter-binding assays. This appears to be the main effect leading to inhibition of integration. Quantitative analysis of filter-binding assay curves indicates that two antibody molecules react with IN implying that the enzyme is dimeric within these experimental conditions. Together, present data provide an insight into the structure-function relationship for the 147-175 peptide domain of the enzyme. They also strongly suggest that the functional enzyme is dimeric. Results could help to assess models for binding of peptide fragments to IN and to develop stronger inhibitors. Moreover, K159 antibodies when expressed in vivo might exhibit useful inhibitory properties.

Comparative structural analysis by [1H,31P]-NMR and restrained molecular dynamics of two DNA hairpins from a strong DNA topoisomerase II cleavage site.

The structural analysis of two single-stranded DNAs d(AGCTTATCATCGATAAGCT) (ATC-19) and d(AGCTTATCGATGATAAGCT) (GAT-19) was performed by NMR and restrained molecular dynamics. These oligonucleotides reproduce the 15-33 segment of phage pBR322 DNA, which contains a strong cleavage site for topoisomerase II coupled to the antitumor drugs VP-16 and ellipticine. Because of their partial palindromic nature, the two oligonucleotides ATC-19 and GAT-19 may fold back into stable hairpin structures, consisting of a stem of eight base-pairs and a loop of three residues. NMR assignments and conformational parameters were determined from combined 2D NOESY, COSY and 1H-31P spectra. Conformations of ATC-19 and GAT-19 hairpins were calculated using the X-PLOR 3.1 program. Structures were generated through simulated annealing procedures starting from 50 structures with randomized torsion angles. A good convergence was observed for ATC-19 molecules, while no consensus was found for GAT-19. Within the GAT-19 loop, the base stacking was poor and no hydrogen bond could be detected. In contrast, ATC-19 displayed a well-defined three residue loop stabilized by both extensive base stackings and hydrogen bonding between the N3 atom of the adenine ring and the amino group of the cytosine ring. The results confirm our earlier ATC-19 structure obtained by a completely different calculation procedure (JUMNA) and the higher thermal stability of ATC-19 compared to GAT-19. Moreover, due to its mismatched base-pair, the ATC-19 loop may be better described as a single residue loop rather than a three residue loop. Comparison of this loop to those containing sheared purine.purine base-pairs revealed striking resemblances, particularly on the backbone angle combination. Finally, the differences observed between the ATC-19 and GAT-19 structures could help toward understanding the sequential cleavage of DNA strands by topoisomerase II.

Helical and coiled-coil-forming properties of peptides derived from and inhibiting human immunodeficiency virus type 1 integrase assessed by 1H-NMR--use of NH temperature coefficients to probe coiled-coil structures.

Human immunodeficiency virus type 1 integrase (HIV-1 IN) which catalyzes viral DNA integration into the host genome of infected cells represents an attractive target for AIDS therapy. We have previously demonstrated the ability of the IN-(147-175)-peptide derived from the catalytic core domain of HIV-1 IN to inhibit the enzyme activity in vitro. IN-(147-175)-peptide contains four heptad repeats and displays a high propensity for coiled-coil formation while its [P159]IN-(147-175)-peptide analog (Lys159-->Pro in the protein, Lys13-->Pro in the peptide) is unable to form a stable coiled-coil and is devoid of inhibitory activity [Sourgen, F., Maroun, R. G., Frère, V., Bouziane, M., Auclair, C., Troalen, F. & Fermandjian, S. (1996) Eur. J. Biochem. 240, 765-773]. Now, we report results from an NMR study on IN-(147-175)-peptide and [P159]IN-(147- 175)-peptide as well as on an optimized [E156, A163, A167]IN-(147-175)-peptide that is a better inhibitor of IN than IN-(147-175)-peptide. While in aqueous solution, IN-(147-175)-peptide and [P159]IN-(147-175)-peptide display only nascent helical features, [E156, A163, A167]IN-(147-175)-peptide exhibits 20% of helical content. In 20% trifluoroethanol/80% H2O, the helix content is the highest for [E156, A163, A167]IN-(147-175)-peptide (approximately 70%) and the lowest for [P159]IN-(147-175)-peptide (approximately 40%), due to a local helix break caused by the Pro residue. The NHs of residues in the two central helical heptads (a-g) of IN-(147-175)-peptide and [E156, A163, A167]IN-(147-175)-peptide display a regular periodic variation of their temperature coefficients in 20% trifluoroethanol. The b, c and f residues on the hydrophilic face of the amphipathic helix show high coefficients reflecting hydrogen bonded NHs, while the a and d residues on the hydrophobic face exhibit low coefficients, near random-coil values. The particular arrangement of the hydrophobic side-chains of a and d residues at the coiled-coil interface reduces the access of trifluoroethanol molecules to their amide groups. The inability of trifluoroethanol molecules to create interactions with the amide C=O groups, these being required to strengthen the intrahelical C=O...H-N hydrogen bonds, is the main cause for observation of heptadic a and d residues with low NH temperature coefficients. Such effects concern mostly the two central helical heptads of IN-(147-175)-peptide and [E156, A163, A167]IN-(147-175)-peptide implying that these ones are engaged in stable parallel coiled coils. Our results provide a link between the propensity of peptides for helix formation, their coiled-coil properties and their efficiency to inhibit IN.

The hairpin structure of a topoisomerase II site DNA strand analyzed by combined NMR and energy minimization methods.

We report on the structural study of the single-stranded 19mer oligonucleotide d(AGCTTATC-ATC-GATAAGCT) 22(+). This corresponds to the 15-to-33(+) strand of pBR322 DNA belonging to a strong cleavage site (site 22) for topoisomerase II coupled to antitumor drugs VP-16 or ellipticine. The partially self-complementary nature of this oligonucleotide makes likely its folding into a hairpin structure. To assess this property we carried out a quantitative analysis based on joint calculations and NMR experiments. The latter required two-dimensional (NOESY, P-COSY, TOCSY and proton-detected 1H-31P), and three-dimensional (NOESY-TOCSY) spectra to achieve the assignment of the overcrowded sugar H4' ad H5'/H5" proton region. For molecular modeling, the JUMNA program was used together with NMR constraints; namely, the distances and the backbone torsion angles provided by NOEs and homo- and heteronuclear coupling constants. Experimental results proved that the 19mer oligonucleotide adopted a stable hairpin structure characterized by an eight base-pair stem and a three-membered loop (central-ATC-segment). Homonuclear 1H-1H and heteronuclear 1H-31P coupling constant measurements provided information on the conformational heterogeneity of the sugar and phosphate groups within both the stem and the loop. Restrained energy minimizations starting with different structures resulted in a family of closely related structures. All low-energy molecules presented the same, rather compact, folded structure with the base-stacking continuing into the loop, a sharp turn occurring between residues T10 and C11, and strong backbone distortions at the loop-stem junction.

A synthetic peptide from the human immunodeficiency virus type-1 integrase exhibits coiled-coil properties and interferes with the in vitro integration activity of the enzyme. Correlated biochemical and spectroscopic results.

Integration of the human immunodeficiency virus (HIV-1) DNA into the host genome is catalysed by a virus-encoded protein integrase. Here, we report some of the structural and functional properties of two synthetic peptides: integrase-(147-175)-peptide reproducing the residues 147-175 (SQGVVESMNKELK159KIIGQVRDQAEHLKTAY) of the HIV-1 integrase, and [Pro159] integrase-(147-175)-peptide where the lysine 159 is substituted for a proline. Circular dichroism revealed that both peptides are mostly under unordered conformation in aqueous solution, contrasting with the alpha-helix exhibited by residues 147-175 in the protein crystal structure. In a weak alpha-helix-promoting environment, integrase-(147-175)-peptide self-associated into stable coiled-coil oligomers, while [Pro159] integrase-(147-175)-peptide did not. This property was further confirmed by cross-linking experiments. In our in vitro experiments, only integrase-(147-175)-peptide was able to reduce the integration activity of the enzyme. We propose that the inhibitory activity shown by integrase-(147-175)-peptide is dependent on its ability to bind to its counterpart in integrase through a peptide-protein coiled-coil structure disturbing the catalytic properties of the enzyme.