HIV-1 Integrase (IN) represents a very attractive pharmacological target for the development of new and more efficient drugs. Recently, an allosteric inhibitory approach also emerged, that targets the interaction between IN and cellular cofactors, such as LEDGF/p75. Small molecules based on the diketoacid pharmachophore were studied for their ability to inhibit at the same time integration and IN-LEDGF/p75 interaction (dual inhibitors): in this study, we evaluated three indole diketoacid derivatives and their magnesium(II) complexes for their ability to act as dual inhibitors. Effectively, the metal complexes exhibited IN inhibition potency in low nanomolar/micromolar concentration range; both the complexes and the free ligands are also able to inhibit the IN-LEDGF/p75 interaction at low μM values. Moreover, these magnesium compounds showed good antiviral activity, suggesting the possibility to exploit metal coordination for the design of new antivirals.

Herein, we report further insight into the biological activities displayed by the 2-hydroxyisoquinoline-1,3(2H,4H)-dione (HID) scaffold. Previous studies have evidenced the marked fruitful effect of substitution of this two-metal binding pharmacophore at position 4 by phenyl and benzyl carboxamido chains. Strong human immunodeficiency virus type 1 integrase (HIV-1 IN) inhibitors in the low nanomolar range with micromolar (even down to low nanomolar) anti-HIV activities were obtained. Keeping this essential 4-carboxamido function, we investigated the influence of the replacement of phenyl and benzyl groups by various alkyl chains. This study shows that the recurrent halogenobenzyl pharmacophore found in the INSTIs can be efficiently replaced by an n-alkyl group. With an optimal length of six carbons, we observed a biological profile and a high barrier to resistance equivalent to those of a previously reported hit compound bearing a 4-fluorobenzyl group.

The disruption of crucial interactions between HIV-1 Integrase and cellular cofactor LEDGF/p75 represents an emerging approach for the design and development of new antiretroviral agents. In this study we report the successful application of a structure-based virtual screening strategy for the discovery of natural hit structures able to inhibit Integrase-LEDGF/p75 interaction. The application of sequential filters (drug-likeness, 3D-pharmacophore mapping, docking, molecular dynamics simulations) yielded a hit list of compounds, out of which 9 were tested in the in vitro AlphaScreen assays and 8 exhibited a detectable inhibition of the interaction between the two proteins. The best inhibitors belong to different chemical classes and could be represent a good starting point for further optimization and structure-activity relationship studies.

A series of N-aryl-naphthylamines, exemplified by the structures 11-16, were chosen for an in-house library screening to assay their ability to disrupt the interaction between the LEDGF cofactor and the HIV integrase. Structure modification led also to design and synthesize new compounds 17a-f. Compounds 11e,h,k,n, 13b, and 14 showed good activity in AlphaScreen assay. The most active compound 11e (IC50 = 2.5 μM) was selected for molecular modeling studies and showed a binding mode similar to the one of the known LEDGIN 8.