Department of Microbiology and Immunology, University of Rochester School of Medicine and Dentistry , Rochester, New York 14642, United States.
Biochemistry. 2013 Jul 23;52(29):4981-90. doi: 10.1021/bi400618q. Epub 2013 Jul 9.
Efavirenz is a non-nucleoside reverse transcriptase inhibitor used for treating HIV/AIDS. We found that polymerization activity of a reverse transcriptase (RT) with the E478Q mutation that inactivates the RNase H catalytic site is much more sensitive to efavirenz than wild-type RT, indicating that a functional RNase H attenuates the effectiveness of efavirenz. Moreover, efavirenz actually stimulated wild-type RNase H binding and catalytic functions, indicating another link between efavirenz action and RNase H function. During reverse transcription in vivo, the RT that is extending the DNA primer also periodically cleaves the genomic RNA. The RNase H makes primary template cuts ~18 nucleotides from the growing DNA 3'-end, and when the RT pauses synthesis, it shifts to make secondary cuts ~9 nucleotides from the DNA 3'-end. After synthesis, RTs return to bind the remaining template RNA segments at their 5'-ends and make primary and secondary cuts, 18 and 9 nucleotides in, respectively. We found that efavirenz stimulates both 3'- and 5'-directed RNase H activity. Use of specific substrates revealed a particular acceleration of secondary cuts. Efavirenz specifically promoted binding of the RT to RNase H substrates, suggesting that it stabilizes the shifting of RTs to make the secondary cuts. We further showed that efavirenz similarly stimulates the RNase H of an RT from a patient-derived virus that is highly resistant and grows more rapidly in the presence of low concentrations of efavirenz. We suggest that for efavirenz-resistant RTs, stimulated RNase H activity contributes to increased viral fitness.
依非韦伦是一种非核苷类逆转录酶抑制剂,用于治疗 HIV/AIDS。我们发现,具有使 RNase H 催化位点失活的 E478Q 突变的逆转录酶 (RT) 的聚合活性对依非韦伦比野生型 RT 更为敏感,这表明功能性 RNase H 会降低依非韦伦的有效性。此外,依非韦伦实际上刺激了野生型 RNase H 的结合和催化功能,这表明依非韦伦作用和 RNase H 功能之间存在另一种联系。在体内逆转录过程中,正在延伸 DNA 引物的 RT 也会周期性地切割基因组 RNA。RNase H 在距生长 DNA 3'-末端约 18 个核苷酸处进行主要模板切割,当 RT 暂停合成时,它会转移到距 DNA 3'-末端约 9 个核苷酸处进行次要切割。合成后,RT 会返回并在其 5'-末端结合剩余的模板 RNA 片段,并进行主要和次要切割,分别在 18 和 9 个核苷酸处。我们发现依非韦伦刺激 3'-和 5'-定向的 RNase H 活性。使用特定的底物发现次要切割特别加速。依非韦伦特异性促进 RT 与 RNase H 底物的结合,表明它稳定了 RT 向次要切割转移的过程。我们进一步表明,依非韦伦以类似的方式刺激来自具有高度耐药性且在低浓度依非韦伦存在下生长更快的源自患者病毒的 RT 的 RNase H。我们认为,对于依非韦伦耐药的 RT,受刺激的 RNase H 活性有助于增加病毒适应性。