Mechanism of interaction of novel indolylarylsulfone derivatives with K103N and Y181I mutant HIV-1 reverse transcriptase in complex with its substrates.

BACKGROUND: Novel indolylarylsulfones (IASs), designed through rational structure-based molecular modelling and docking approaches, have been recently characterized as effective inhibitors of the wild-type and drug-resistant mutant HIV-1 reverse transcriptase (RT). METHODS: Here, we studied the interaction of selected halo- and nitro-substituted IAS derivatives, with the RT enzyme carrying the single resistance mutations K103N and Y181I through steady-state kinetic experiments. RESULTS: The studied compounds exhibited high selectivity to the mutant RT in complex with its substrates, behaving as uncompetitive inhibitors. The presence of the K103N mutation, and to a lesser extent the Y181I, stabilized the drug interactions with the viral RT, when both its substrates were bound. CONCLUSIONS: The characterization of these mutation-specific effects on inhibitor binding might be relevant to the design of more effective new generation non-nucleoside reverse transcriptase inhibitors, with better resilience towards drug resistant mutants.

Mutational analysis of the HIV-1 auxiliary protein Vif identifies independent domains important for the physical and functional interaction with HIV-1 reverse transcriptase.

The HIV-1 accessory protein Vif plays a dual role: it counteracts the natural restriction factors APOBEC3G and 3F and ensures efficient retrotranscription of the HIV-1 RNA genome. We have previously shown that Vif can act as an auxiliary factor for HIV-1 reverse transcriptase (RT), increasing its rate of association to RNA or DNA templates. Here, by using seven different Vif mutants, we provide in vitro evidences that Vif stimulates HIV-1 RT through direct protein-protein interaction, which is mediated by its C-terminal domain. Physical interaction appears to require the proline-rich region comprised between amino acid (aa) 161 and 164 of Vif, whereas the RT stimulatory activity requires, in addition, the extreme C-terminal region (aa 169-192) of the Vif protein. Neither the RNA interaction domain, nor the Zn(++)-binding domain of Vif are required for its interaction with the viral RT. Pseudotyped HIV-1 lentiviral vectors bearing Vif mutants deleted in the RNA- or RT-binding domains show defects in retrotranscription/integration processes in both permissive and nonpermissive cells. Our results broaden our knowledge on how three important functions of Vif (RNA binding, RT binding and stimulation and Zn(++) binding), are coordinated by different domains.

Non-nucleoside HIV-1 reverse transcriptase inhibitors di-halo-indolyl aryl sulfones achieve tight binding to drug-resistant mutants by targeting the enzyme-substrate complex.

Indolyl aryl sulfone (IAS) non-nucleoside reverse transcriptase (RT) inhibitors (NNRTIs) have been previously shown to effectively inhibit wild-type (wt) and drug-resistant human immunodeficiency virus type 1 (HIV-1) replication. IASs proved to act through different mechanisms of action, depending on the nature and position of their chemical substituents. Here we describe selected novel IAS derivatives (di-halo-IASs). Our results show that these compounds are selective for the enzyme-substrate complex. The molecular basis for this selectivity was a different dissociation rate of the drug to a particular enzymatic form along the reaction pathway. By comparing the activities of the different compounds against wild-type RT and the resistant enzymes carrying the single mutations Lys103Asn, Leu100Ile, and Tyr181Ile (K103N, L100I, and Y181I), we found that one compound (RS1914) dissociated from the mutated enzymes almost 10-fold slower than from the wild type RT. These results demonstrate that IASs are very flexible molecules, interacting dynamically with the viral RT, and that this property can be successfully exploited to design inhibitors endowed with an enhanced binding to common NNRTI-resistant mutants.