Abstract
HIV-1 integration into the human genome is dependent on 3'-processing of the viral DNA. Recently, we reported that the cellular Three Prime Repair Exonuclease 1 (TREX1) enhances HIV-1 integration by degrading the unprocessed viral DNA, while the integration-competent 3'-processed DNA remained resistant. Here, we describe the mechanism by which the 3'-processed HIV-1 DNA resists TREX1-mediated degradation. Our kinetic studies revealed that the rate of cleavage (k(cat)) of the 3'-processed DNA was significantly lower (approximately 2-2.5-fold) than the unprocessed HIV-1 DNA by TREX1. The k(cat) values of human TREX1 for the processed U5 and U3 DNA substrates were 3.8 s(-1) and 4.5 s(-1), respectively. In contrast, the unprocessed U5 and U3 substrates were cleaved at 10.2 s(-1) and 9.8 s(-1), respectively. The efficiency of degradation (k(cat)/K(m)) of the 3'-processed DNA (U5-70.2 and U3-28.05 pM(-1)s(-1)) was also significantly lower than the unprocessed DNA (U5-103.1 and U3-65.3 pM(-1)s(-1)). Furthermore, the binding affinity (K(d)) of TREX1 was markedly lower (∼2-fold) for the 3'-processed DNA than the unprocessed DNA. Molecular docking and dynamics studies revealed distinct conformational binding modes of TREX1 with the 3'-processed and unprocessed HIV-1 DNA. Particularly, the unprocessed DNA was favorably positioned in the active site with polar interactions with the catalytic residues of TREX1. Additionally, a stable complex was formed between TREX1 and the unprocessed DNA compared the 3'-processed DNA. These results pinpoint the mechanism by which TREX1 preferentially degrades the integration-incompetent HIV-1 DNA and reveal the unique structural and conformational properties of the integration-competent 3'-processed HIV-1 DNA.