| Abstract: | The existence of drug-resistant human immunodeficiency virus (HIV) viruses in patients receiving antiretroviral treatment urgently requires the characterization and development of new antiretroviral drugs designed to inhibit resistant viruses and to complement the existing antiretroviral strategies against AIDS. We assayed several natural or semi-synthetic lupane-type pentacyclic triterpenes in their ability to inhibit HIV-1 infection in permissive cells. We observed that the 30-oxo-calenduladiol triterpene, compound 1, specifically impaired R5-tropic HIV-1 envelope-mediated viral infection and cell fusion in permissive cells, without affecting X4-tropic virus. This lupane derivative competed for the binding of a specific anti-CCR5 monoclonal antibody or the natural CCL5 chemokine to the CCR5 viral coreceptor with high affinity. 30-Oxo-calenduladiol seems not to interact with the CD4 antigen, the main HIV receptor, or the CXCR4 viral coreceptor. Our results suggest that compound 1 is a specific CCR5 antagonist, because it binds to the CCR5 receptor without triggering cell signaling or receptor internalization, and inhibits RANTES (regulated on activation normal T cell expressed and secreted)-mediated CCR5 internalization, intracellular calcium mobilization, and cell chemotaxis. Furthermore, compound 1 appeared not to interact with β-chemokine receptors CCR1, CCR2b, CCR3, or CCR4. Thereby, the 30-oxo-calenduladiol-associated anti-HIV-1 activity against R5-tropic virus appears to rely on the selective occupancy of the CCR5 receptor to inhibit CCR5-mediated HIV-1 infection. Therefore, it is plausible that the chemical structure of 30-oxo-calenduladiol or other related dihydroxylated lupane-type triterpenes could represent a good model to develop more potent anti-HIV-1 molecules to inhibit viral infection by interfering with early fusion and entry steps in the HIV life cycle.The human immunodeficiency virus (HIV)7 pandemic is a medical challenge and represents the public health crisis of our time (1–5). Antiretroviral treatment achieves long-lasting viral suppression and, subsequently, reduces the morbidity and mortality of HIV-infected individuals. However, current drugs do not eradicate HIV infection and lifelong treatment might be needed (2).Emerging drug-resistant HIV viruses, in patients receiving high active antiretroviral treatment, urgently needs the development of new antiretroviral molecules designed to inhibit resistant viruses, because many patients treated during the past decades harbor viral strains with reduced susceptibilities to many if not all available drugs (2, 6). In this matter, pentacyclic triterpenes represent a varied class of natural products presenting antitumor and antiviral activities (7–9). A well studied pentacyclic lupane-type triterpene is the betulinic acid (3β-hydroxy-lup-20(29)-en-28-oic acid), widely distributed throughout the plant kingdom, which presents anti-inflammatory, anti-malarial, and anti-HIV-1 effects in vitro (7, 9, 10). Although its mechanism of action has not been fully determined, it has been reported that some lupane-type triterpene derivatives impair HIV-1 fusion through interacting with the viral glycoprotein gp41, or disrupting the assembly and budding of emerging viral particles in infected target cells (reviewed in Ref. 9).In the present work, we aimed to test the ability of several non-acid lupane-type triterpene, natural or derivative compounds, to inhibit HIV-1 viral infection and to determine the mechanism of action. Our results indicate that the semi-synthetic 30-oxo-calenduladiol, compound 1, specifically interacts with the G protein-coupled CCR5 chemokine receptor, acting as an antagonist, inhibiting R5-tropic HIV-1 viral infection and CCL5 (regulated on activation normal T expressed and secreted (RANTES) chemokine)-mediated CCR5 internalization, cell signaling, and chemotaxis. |
