Mechanism of resistance to GS-9148 conferred by the Q151L mutation in HIV-1 reverse transcriptase.

GS-9148 is an investigational phosphonate nucleotide analogue inhibitor of reverse transcriptase (RT) (NtRTI) of human immunodeficiency virus type 1 (HIV-1). This compound is an adenosine derivative with a 2',3'-dihydrofuran ring structure that contains a 2'-fluoro group. The resistance profile of GS-9148 is unique in that the inhibitor can select for the very rare Q151L mutation in HIV-1 RT as a pathway to resistance. Q151L is not stably selected by any of the approved nucleoside or nucleotide analogues; however, it may be a transient intermediate that leads to the related Q151M mutation, which confers resistance to multiple compounds that belong to this class of RT inhibitors. Here, we employed pre-steady-state kinetics to study the impact of Q151L on substrate and inhibitor binding and the catalytic rate of incorporation. Most importantly, we found that the Q151L mutant is unable to incorporate GS-9148 under single-turnover conditions. Interference experiments showed that the presence of GS-9148-diphosphate, i.e., the active form of the inhibitor, does not reduce the efficiency of incorporation for the natural counterpart. We therefore conclude that Q151L severely compromises binding of GS-9148-diphosphate to RT. This effect is highly specific, since we also demonstrate that another NtRTI, tenofovir, is incorporated with selectivity similar to that seen with wild-type RT. Incorporation assays with other related compounds and models based on the RT/DNA/GS-9148-diphosphate crystal structure suggest that the 2'-fluoro group of GS-9148 may cause steric hindrance with the side chain of the Q151L mutant.

Examining the ribonuclease H primer grip of HIV-1 reverse transcriptase by charge neutralization of RNA/DNA hybrids.

The crystal structure of human immunodeficiency virus type 1 (HIV-1) reverse transcriptase (RT) bound to an RNA/DNA hybrid reveals an extensive network of contacts with the phosphate backbone of the DNA strand approximately 4-9 bp downstream from the ribonuclease H (RNase H) catalytic center. Collectively designated as 'the RNase H primer grip', this motif contains a phosphate binding pocket analogous to the human and Bacillus halodurans RNases H. The notion that the RNase H primer grip mediates the trajectory of RNA/DNA hybrids accessing the RNase H active site suggests that locally neutralizing the phosphate backbone may be exploited to manipulate nucleic acid flexibility. To examine this, we introduced single and tandem methylphosphonate substitutions through the region of the DNA primer contacted by the RNase H primer grip and into the RNase H catalytic center. The ability of mutant hybrids to support RNase H and DNA polymerase activity was thereafter examined. In addition, site-specific chemical footprinting was used to evaluate movement of the DNA polymerase and RNase H domains. We show here that minor alteration to the RNase H primer can have a dramatic effect on enzyme positioning, and discuss these findings in light of recent crystallography of human RNase H containing an RNA/DNA hybrid.

Mutations M184V and Y115F in HIV-1 reverse transcriptase discriminate against "nucleotide-competing reverse transcriptase inhibitors".

Indolopyridones are potent inhibitors of reverse transcriptase (RT) of the human immunodeficiency virus type 1 (HIV-1). Although the structure of these compounds differs from established nucleoside analogue RT inhibitors (NRTIs), previous studies suggest that the prototype compound INDOPY-1 may bind in close proximity to the polymerase active site. NRTI-associated mutations that are clustered around the active site confer decreased, e.g. M184V and Y115F, or increased, e.g. K65R, susceptibility to INDOPY-1. Here we have studied the underlying biochemical mechanism. RT enzymes containing the isolated mutations M184V and Y115F cause 2-3-fold increases in IC(50) values, while the combination of the two mutations causes a >15-fold increase. K65R can partially counteract these effects. Binding studies revealed that the M184V change reduces the affinity to INDOPY-1, while Y115F facilitates binding of the natural nucleotide substrate and the combined effects enhance the ability of the enzyme to discriminate against the inhibitor. Studies with other strategic mutations at residues Phe-61 and Ala-62, as well as the use of chemically modified templates shed further light on the putative binding site of the inhibitor and ternary complex formation. An abasic site residue at position n, i.e. opposite the 3'-end of the primer, prevents binding of INDOPY-1, while an abasic site at the adjacent position n+1 has no effect. Collectively, our findings provide strong evidence to suggest that INDOPY-1 can compete with natural deoxynucleoside triphosphates (dNTPs). We therefore propose to refer to members of this class of compounds as "nucleotide-competing RT inhibitors" (NcRTIs).

Connection domain mutations N348I and A360V in HIV-1 reverse transcriptase enhance resistance to 3'-azido-3'-deoxythymidine through both RNase H-dependent and -independent mechanisms.

Thymidine analogue-associated mutations (TAMs) in reverse transcriptase (RT) of the human immunodeficiency virus type 1 (HIV-1) cause resistance to 3'-azido-3'-deoxythymidine (AZT) through excision of the incorporated monophosphate. Mutations in the connection domain of HIV-1 RT can augment AZT resistance. It has been suggested that these mutations compromise RNase H cleavage, providing more time for AZT excision to occur. However, the underlying mechanism remains elusive. Here, we focused on connection mutations N348I and A360V that are frequently observed in clinical samples of treatment-experienced patients. We show that both N348I and A360V, in combination with TAMs, decrease the efficiency of RNase H cleavage and increase excision of AZT in the presence of the pyrophosphate donor ATP. The TAMs/N348I/A360V mutant accumulates transiently formed, shorter hybrids that can rebind to RT before the template is irreversibly degraded. These hybrids dissociate selectively from the RNase H-competent complex, whereas binding in the polymerase-competent mode is either not affected with N348I or modestly improved with A360V. Both connection domain mutations can compensate for TAM-mediated deficits in processive DNA synthesis, and experiments with RNase H negative mutant enzymes confirm an RNase H-independent contribution to increased levels of resistance to AZT. Moreover, the combination of diminished RNase H cleavage and increased processivity renders the use of both PP(i) and ATP advantageous, whereas classic TAMs solely enhance the ATP-dependent reaction. Taken together, our findings demonstrate that distinct, complementary mechanisms can contribute to higher levels of excision of AZT, which in turn can amplify resistance to this drug.

Exploring mitochondrial nephrotoxicity as a potential mechanism of kidney dysfunction among HIV-infected patients on highly active antiretroviral therapy.

BACKGROUND: Tenofovir (TDF) exposure has been associated with renal dysfunction. Mitochondrial nephrotoxicity was investigated as an underlying mechanism. Given the interaction between TDF and didanosine (ddl), their concurrent use was also investigated. DESIGN: Relative kidney biopsy mitochondrial DNA (mtDNA) to nuclear DNA ratios were measured retrospectively. HIV+ individuals on TDF within 6 months preceeding the biopsy (HIV+/TDF+, n=21) were compared to HIV+ individuals who never received TDF (HIV+/TDF-, n=10) and to HIV uninfected controls (HIV-,n=22). Twelve of the HIV+/TDF+ individuals received concurrent ddl, 10 of those once at unadjusted ddl dosage. Tubular mitochondria morphology was also examined by electron microscopy. Statistical analyses were done on log-transformed mtDNA/nDNA, using non-parametric tests. RESULTS: Kidney mtDNA levels were different among the three groups (P=0.046). mtDNA ratios were lower in HIV+/TDF+ subjects (7.5 [2.0-12.1]) than in HIV- ones (14.3 [6.0-16.5], P=0.014), but not lower than HIV+/TDF- controls (6.4 [2.8-11.9], P=0.82). Among HIV+ subjects, there was a difference between TDF-, TDF+/ddl- and TDF+/ddl+ (P=0.005), with concurrent TDF/ddl use associated with lower mtDNA (2.1 [1.9-5.5], n=12) than TDF+/ddl- (13.8 [7.5-16.4], n=9, P=0.003). No TDF-/ddl+ biopsies were available. In regression analyses, only HIV infection (P=0.03), and TDF/ddl use (P=0.003) were associated with lower mtDNA. At the ultrastructural level, abnormal tubular mitochondria was more prevalent in HIV+/TDF+ biopsies than HIV+/TDF- and HIV- ones together (P<0.001) but not more so in TDF+/ddl+ biopsies than TDF+/ddl- ones (P=0.67). CONCLUSIONS: Renal dysfunction in this population may be mediated through mitochondrial nephrotoxicity that involves more than one drug and/or pathogenesis. Kidney mtDNA depletion was associated with HIV infection and concurrent TDF/ddl therapy but not TDF use alone, while kidney ultrastructural mitochondrial abnormalities were seen with TDF use. The interaction between TDF and ddl may be relevant in the kidney where both drugs are cleared. The clinical relevance of our findings needs to be evaluated given the current recommendation for reduced doses of ddl when used in conjunction with TDF.