Abstract
Drug resistance-associated mutations in HIV-1 reverse transcriptase (RT) can affect the balance between polymerase and ribonuclease H (RNase H) activities of the enzyme. We have recently demonstrated that the N348I mutation in the connection domain causes selective dissociation from RNase H-competent complexes, whereas the functional integrity of the polymerase-competent complex remains largely unaffected. N348I has been associated with resistance to the non-nucleoside RT inhibitor (NNRTI), nevirapine; however, a possible mechanism that links changes in RNase H activity to changes in NNRTI susceptibility remains to be established. To address this problem, we consider recent findings suggesting that NNRTIs may affect the orientation of RT on its nucleic acid substrate and increase RNase H activity. Here we demonstrate that RNase H-mediated primer removal is indeed more efficient in the presence of NNRTIs; however, the N348I mutant enzyme is able to counteract this effect. Efavirenz, a tight binding inhibitor, restricts the influence of the mutation. These findings provide strong evidence to suggest that N348I can thwart the inhibitory effects of nevirapine during initiation of (+)-strand DNA synthesis, which provides a novel mechanism for resistance. The data are in agreement with clinical data, which demonstrate a stronger effect of N348I on susceptibility to nevirapine as compared with efavirenz.
Highlights
Strand, namely (Ϫ)-strand DNA, by extending the 3Ј-end of a tRNA primer, the reverse transcriptase (RT)-associated ribonuclease H (RNase H) activity degrades the transcribed RNA of the newly synthesized DNA1⁄7RNA hybrid
During (ϩ)-strand initiation, Combined Effects of non-nucleoside RT inhibitor (NNRTI) and N348I on DNA1⁄7RNA and RT can bind its substrate in two different orientations (Fig. 1B) RNA1⁄7DNA Primer1⁄7Template Substrates—We studied the that permit DNA synthesis or RNase H activity
RNase H-dependent Contribution to NVP Resistance—We investigated the efficiency of RNase H cleavage on To assess whether the diminished RNase H activity associthe *17r8d1⁄757d substrate that is generated during the initiation ated with N348I translates into increased production of of (ϩ)-strand DNA synthesis to assess whether NNRTIs restore full-length DNA, we monitored the reaction under multiple
Summary
Strand, namely (Ϫ)-strand DNA, by extending the 3Ј-end of a tRNA primer, the RT-associated RNase H activity degrades the transcribed RNA of the newly synthesized DNA1⁄7RNA hybrid. During the initiation of (ϩ)-strand DNA synthesis, HIV-1 diminishes polymerase-independent RNase H cleavage during During (ϩ)-strand initiation, Combined Effects of NNRTIs and N348I on DNA1⁄7RNA and RT can bind its substrate in two different orientations (Fig. 1B) RNA1⁄7DNA Primer1⁄7Template Substrates—We studied the that permit DNA synthesis or RNase H activity.
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