The integration of reverse transcribed proviral DNA into a host genome is an essential event in the human immunodeficiency virus type 1 (HIV-1) replication life cycle. Therefore, the viral enzyme integrase (IN), which plays a crucial role in the integration event, has been an attractive target of anti-retroviral drugs. Several IN inhibitory compounds have been reported previously, yet none has been successful in clinical use. To find a new, more successful IN inhibitor, we screened a diverse library of 12000 small molecular weight compounds randomly by in vitro strand-transfer assay. We identified a series of substituted carbazoles that exhibit strand-transfer inhibitory activity at low micromolar concentrations. Of these, the most potent compound exhibited an IC50 of 5.00 ±3.31 μM (CA-0). To analyse the structural determinants of strand-transfer inhibitory activity of the carbazole derivatives, we selected 23 such derivatives from our compound library and performed further analyses. Of these 23 compounds, six showed strong strand-transfer inhibition. The inhibition kinetics analyses and ethidium bromide displacement assays indicated that the carbazole derivatives are competitive inhibitors and not intercalators. An HeLa4.5/LTR-nEGFP cell line was employed to evaluate in vitro virus replication inhibition of the carbazole derivatives, and IC50 levels ranged from 0.48–1.52 μM. Thus, it is possible that carbazole derivatives, which possess structures different from previously-reported IN inhibitors, may become novel lead compounds in the development of IN inhibitors.
Release of interleukin 1 inhibitory activity (contra-IL-1) by human monocyte-derived macrophages infected with human immunodeficiency virus in vitro and in vivo.