Single-Particle Tracking Reveals the Interplay between HIV-1 Reverse Transcription and Uncoating.

Reverse transcription uses the reverse transcriptase enzyme to synthesize deoxyribonucleic acid (DNA) from a ribonucleic acid (RNA) template. This plays an essential role in viral replication. There are still, however, many unknown facts regarding the timing and dynamic processes involved in this life stage. Here, three types of dual-fluorescence human immunodeficiency virus type-1 (HIV-1) particles were constructed with high infectivity, and the sequential process of reverse transcription was observed by real-time imaging of a single HIV-1 particle. Viral uncoating occurred at 60-120 min post infection. Subsequently, at 120-180 min post infection, the viral genome was separated into two parts and reverse-transcribed to generate a DNA product. Nevirapine (NVP), a reverse transcriptase inhibitor, can delay the dynamic process. This study revealed a delicate, sequential, and complex relationship between uncoating and reverse transcription, which may facilitate the development of antiviral drugs.

Factors that mold the nuclear landscape of HIV-1 integration.

The integration of retroviral reverse transcripts into the chromatin of the cells that they infect is required for virus replication. Retroviral integration has far-reaching consequences, from perpetuating deadly human diseases to molding metazoan evolution. The lentivirus human immunodeficiency virus 1 (HIV-1), which is the causative agent of the AIDS pandemic, efficiently infects interphase cells due to the active nuclear import of its preintegration complex (PIC). To enable integration, the PIC must navigate the densely-packed nuclear environment where the genome is organized into different chromatin states of varying accessibility in accordance with cellular needs. The HIV-1 capsid protein interacts with specific host factors to facilitate PIC nuclear import, while additional interactions of viral integrase, the enzyme responsible for viral DNA integration, with cellular nuclear proteins and nucleobases guide integration to specific chromosomal sites. HIV-1 integration favors transcriptionally active chromatin such as speckle-associated domains and disfavors heterochromatin including lamina-associated domains. In this review, we describe virus-host interactions that facilitate HIV-1 PIC nuclear import and integration site targeting, highlighting commonalities among factors that participate in both of these steps. We moreover discuss how the nuclear landscape influences HIV-1 integration site selection as well as the establishment of active versus latent virus infection.

Mechanism of polypurine tract primer generation by HIV-1 reverse transcriptase.

HIV-1 reverse transcriptase (RT) possesses both DNA polymerase activity and RNase H activity that act in concert to convert single-stranded RNA of the viral genome to double-stranded DNA that is then integrated into the DNA of the infected cell. Reverse transcriptase-catalyzed reverse transcription critically relies on the proper generation of a polypurine tract (PPT) primer. However, the mechanism of PPT primer generation and the features of the PPT sequence that are critical for its recognition by HIV-1 RT remain unclear. Here, we used a chemical cross-linking method together with molecular dynamics simulations and single-molecule assays to study the mechanism of PPT primer generation. We found that the PPT was specifically and properly recognized within covalently tethered HIV-1 RT-nucleic acid complexes. These findings indicated that recognition of the PPT occurs within a stable catalytic complex after its formation. We found that this unique recognition is based on two complementary elements that rely on the PPT sequence: RNase H sequence preference and incompatibility of the poly(rA/dT) tract of the PPT with the nucleic acid conformation that is required for RNase H cleavage. The latter results from rigidity of the poly(rA/dT) tract and leads to base-pair slippage of this sequence upon deformation into a catalytically relevant geometry. In summary, our results reveal an unexpected mechanism of PPT primer generation based on specific dynamic properties of the poly(rA/dT) segment and help advance our understanding of the mechanisms in viral RNA reverse transcription.

Structural insight into HIV-1 reverse transcription initiation in MAL-like templates (CRF01_AE, subtype G and CRF02_AG).

Based on the known structural model for reverse transcription initiation complex of the human immunodeficiency virus type 1 (HIV-1) MAL isolate, we attempted to predict a structural behavior of MAL-like templates (CRF01_AE, subtype G and CRF02_AG) within the initiation complex by in silico experiments. Switches from the D-duplex (dimerization-competent) conformation to the I-duplex (initiation-competent) conformation and then to conformations with an open primer activation signal (PAS) structure have been examined for four fragments of U5 and primer binding site (PBS) region, the minimal fragment (nt 121-243), fragment 1 (nt 110-243), fragment 2 (nt 113-259), and extended fragment 2 (nt 109-261). Switches from the D-duplex conformation to the I-duplex conformation in the minimal fragment or fragment 1 and from the I-duplex conformation to conformations with exposed PAS motif in fragment 1 are similar in all MAL-like templates. A PAS exposure in fragment 2 and extended fragment 2 is supported by PBS stem extension which structure is affected by subtype-specific variations in CRF01_AE (the mutated motif (116)GUUAG(120)) and CRF02_AG (7-nt deletion downstream of the PBS motif and G/C/A insertion at the 3' end of fragment 2). These switchable conformations contain the established structural elements essential for HIV-1 reverse transcription initiation as well as several elements that may also be relevant to initiation process, namely hairpins with GAAA apical loops and self-contained motifs of the duplicate insertion and the downstream palindromic sequence. Taken together, our findings suggest a role for the duplicate insertion of MAL-like templates in HIV-1 reverse transcription initiation process and possible mechanisms to realize this role.

[Viral and host factors affecting efficient revere transcription of HIV-1 genome].

Reverse transcription of retroviral RNA into double stranded DNA is a characteristic feature of rertoviruses including human immunodeficiency virus type I (HIV-1). There has been accumulating evidence for the involvement of retroviral integrase (IN) in the reverse transcription of viral RNA. Here, we summarized recent our studies demonstrating direct functional roles of IN and its binding partner of host factor, Gemin2 in the reverse transcription. We established new in vitro cell-free assay to mimic natural reverse transcription and found that HIV-1 IN and host factor, Gemin2 synergistically stimulate reverse transcriptase (RT) activity. Analysis of intracellular stability and multimer formation of IN suggest that that high-ordered structures, especially tetramer formation of IN is critical for the function. In addition, Gemin2 might have a role to keep the higher-order structure of IN. Thus, we provide new aspects of reverse transcription of HIV-1 through IN and host factors in addition to RT.

K65R and K65A substitutions in HIV-1 reverse transcriptase enhance polymerase fidelity by decreasing both dNTP misinsertion and mispaired primer extension efficiencies.

Lys65 residue, in the fingers domain of human immunodeficiency virus reverse transcriptase (RT), interacts with incoming dNTP in a sequence-independent fashion. We showed previously that a 5-amino-acid deletion spanning Lys65 and a K65A substitution both enhanced the fidelity of dNTP insertion. We hypothesized that the Lys65 residue enhances dNTP misinsertion via interactions with the gamma-phosphate of the incoming dNTP. We now examine this hypothesis in pre-steady-state kinetic studies using wild-type human immunodeficiency virus-1 RT and two substitution mutants, K65A and K65R. K65R mutation did not greatly increase misinsertion fidelity, but K65A mutation led to higher incorporation fidelity. For a misinsertion to become a permanent error, it needs to be accompanied by the extension of the mispaired terminus thus formed. Both mutants and the wild-type enzyme discriminated against the mismatched primer at the catalytic step (k(pol)). Additionally, K65A and K65R mutants displayed a further decrease in mismatch extension efficiency, primarily at the level of dNTP binding. We employed hydroxyl radical footprinting to determine the position of the RT on the primer/template. The wild-type and Lys65-substituted enzymes occupied the same position at the primer terminus; the presence of a mismatched primer terminus caused all three enzymes to be displaced to a -2 position relative to the primer 3' end. In the context of an efficiently extended mismatched terminus, the presence of the next complementary nucleotide overcame the displacement, resulting in a complex resembling the matched terminus. The results are consistent with the observed reduction in k(pol) in mispaired primer extension being due to the position of the enzyme at a mismatched terminus. Our work shows the influence of the stabilizing interactions of Lys65 with the incoming dNTP on two different aspects of polymerase fidelity.

Structural basis for the role of the K65R mutation in HIV-1 reverse transcriptase polymerization, excision antagonism, and tenofovir resistance.

K65R is a primary reverse transcriptase (RT) mutation selected in human immunodeficiency virus type 1-infected patients taking antiretroviral regimens containing tenofovir disoproxil fumarate or other nucleoside analog RT drugs. We determined the crystal structures of K65R mutant RT cross-linked to double-stranded DNA and in complexes with tenofovir diphosphate (TFV-DP) or dATP. The crystals permit substitution of TFV-DP with dATP at the dNTP-binding site. The guanidinium planes of the arginines K65R and Arg(72) were stacked to form a molecular platform that restricts the conformational adaptability of both of the residues, which explains the negative effects of the K65R mutation on nucleotide incorporation and on excision. Furthermore, the guanidinium planes of K65R and Arg(72) were stacked in two different rotameric conformations in TFV-DP- and dATP-bound structures that may help explain how K65R RT discriminates the drug from substrates. These K65R-mediated effects on RT structure and function help us to visualize the complex interaction with other key nucleotide RT drug resistance mutations, such as M184V, L74V, and thymidine analog resistance mutations.

Increased thermostability and fidelity of DNA synthesis of wild-type and mutant HIV-1 group O reverse transcriptases.

Reverse transcription coupled with DNA amplification has become a well-established and powerful molecular technique for studying ribonucleic acids. However, the efficiency of those reactions is largely dependent on the molecular properties of currently used reverse transcriptases (RTs). Engineered and natural RT variants with improved thermostability and fidelity of DNA synthesis should be of great utility in the amplification of RNA targets. In this study, we demonstrate that the wild-type (WT) HIV-1 group O (O_WT) RT shows increased thermostability in comparison with Moloney murine leukemia virus RT and a prototypic HIV-1 group M:subtype B (BH10_WT) RT, while rendering higher yields in reverse transcription PCRs that included a cDNA synthesis step performed at a high temperature range (57-69 degrees C). In addition, the O_WT RT showed 2.5-fold increased accuracy in M13 lacZalpha forward mutation assays in comparison with the BH10_WT RT. Unlike the BH10_WT enzyme, O_WT RT showed a very low error rate for frameshifts. Mutational hot spots induced by O_WT RT occurred at nucleotide runs, suggesting a dislocation-mediated mechanism for the generation of base substitutions. In HIV-1 group O RT, substituting Ile75 for Val rendered an enzyme that was 1.9 and 4.7 times more faithful than O_WT RT and BH10_WT RTs, respectively, in forward mutation assays. The mutant RT also showed increased misinsertion and mispair extension fidelity in kinetic assays. However, its mutational spectrum was similar to that obtained with the WT group O polymerase. V75I caused a loss of efficiency of reverse transcription PCR amplifications at 65 and 68 degrees C in comparison with O_WT RT. However, a double mutant devoid of RNase H activity (V75I/E478Q) was found to reverse-transcribe at temperatures as high as 68 degrees C, while maintaining the increased accuracy of the V75I mutant.

Mechanism by which a glutamine to leucine substitution at residue 509 in the ribonuclease H domain of HIV-1 reverse transcriptase confers zidovudine resistance.

We recently reported that zidovudine (AZT) selected for the Q509L mutation in the ribonuclease H (RNase H) domain of HIV-1 reverse transcriptase (RT), which increases resistance to AZT in combination with the thymidine analogue mutations D67N, K70R, and T215F. In the current study, we have defined the mechanism by which Q509L confers AZT resistance by performing in-depth biochemical analyses of wild type, D67N/K70R/T215F and D67N/K70R/T215F/Q509L HIV-1 RT. Our results show that Q509L increases AZT-monophosphate (AZT-MP) excision activity of RT on RNA/DNA template/primers (T/Ps) but not DNA/DNA T/Ps. This increase in excision activity on the RNA/DNA T/P is due to Q509L decreasing a secondary RNase H cleavage event that reduces the RNA/DNA duplex length to 10 nucleotides and significantly impairs the enzyme's ability to excise the chain-terminating nucleotide. Presteady-state kinetic analyses indicate that Q509L does not affect initial rates of the polymerase-directed RNase H activity but only polymerase-independent cleavages that occur after a T/P dissociation event. Furthermore, competition binding assays suggest that Q509L decreases the affinity of the enzyme to bind T/P with duplex lengths less than 18 nucleotides in the polymerase-independent RNase H cleavage mode, while not affecting the enzyme's affinity to bind the same T/P in an AZT-MP excision competent mode. Taken together, this study provides the first mechanistic insights into how a mutation in the RNase H domain of RT increases AZT resistance and highlights how the polymerase and RNase H domains of RT function in concert to confer drug resistance.

Delayed chain termination protects the anti-hepatitis B virus drug entecavir from excision by HIV-1 reverse transcriptase.

Entecavir (ETV) is a potent antiviral nucleoside analogue that is used to treat hepatitis B virus (HBV) infection. Recent clinical studies have demonstrated that ETV is also active against the human immunodeficiency virus type 1 (HIV-1). Unlike all approved nucleoside analogue reverse transcriptase RT) inhibitors (NRTIs), ETV contains a 3'-hydroxyl group that allows further nucleotide incorporation events to occur. Thus, the mechanism of inhibition probably differs from classic chain termination. Here, we show that the incorporated ETV-monophosphate (MP) can interfere with three distinct stages of DNA synthesis. First, incorporation of the next nucleotide at position n + 1 following ETV-MP is compromised, although DNA synthesis eventually continues. Second, strong pausing at position n + 3 suggests a long range effect, referred to as "delayed chain-termination." Third, the incorporated ETV-MP can also act as a "base pair confounder" during synthesis of the second DNA strand, when the RT enzyme needs to pass the inhibitor in the template. Enzyme kinetics revealed that delayed chain termination is the dominant mechanism of action. High resolution foot-printing experiments suggest that the incorporated ETV-MP "repels" the 3'-end of the primer from the active site of HIV-1 RT, which, in turn, diminishes incorporation of the natural nucleotide substrate at position n + 4. Most importantly, delayed chain termination protects ETV-MP from phosphorolytic excision, which represents a major resistance mechanism for approved NRTIs. Collectively, these findings provide a rationale and important tools for the development of novel, more potent delayed chain terminators as anti-HIV agents.

Ile178 of HIV-1 reverse transcriptase is critical for inhibiting the viral integrase.

HIV-1 reverse transcriptase (RT) was shown to inhibit in vitro the viral integrase (IN). We have reported previously that an RT-derived 20-residue peptide binds IN and inhibits its enzymatic activities. In this peptide, Leu168, Phe171, Gln174, and Ile178 were predicted to be involved in IN inhibition. In the presented study, these residues were mutagenized and the resulting peptides were tested for binding and inhibiting IN activities. Ile178 was found to be the major contributor to IN inhibition, probably by interacting with IN residue Gly149. As Gly149 is a key IN residue, this inhibition probably results from a steric hindrance of the IN active site.

Insights into the multiple roles of pausing in HIV-1 reverse transcriptase-promoted strand transfers.

We previously analyzed the role of pausing induced by hairpin structures within RNA templates in facilitating strand transfer by HIV-1 RT (reverse transcriptase). We proposed a multistep transfer mechanism in which pause-induced RNase H cuts within the initial RNA template (donor) expose regions of cDNA. A second homologous RNA template (acceptor) can interact with the cDNA at such sites, initiating transfer. The acceptor-cDNA hybrid is thought to then propagate by branch-migration, eventually catching up with the primer terminus and completing the transfer. The prominent pause site in the template system facilitated acceptor invasion; however, very few of the transfers terminated at this pause. To examine the effects of homology on pause-promoted transfer, we increased template homology before the pause site, from 19 nucleotides (nt) in the initial template system to 52 nt in the new system. Significantly, the increased homology enhanced transfers 3-fold, with 32% of the transfers now terminating at the pause site. Additionally, the acceptor cleavage profile indicated the creation of a new invasion site in the added region of homology. NC (nucleocapsid) increased the strand transfer throughout the whole template. However, the prominent hot spot for internal transfer remained, which was still at the pause site. We interpret the new results to mean that pause sites can also serve to stall DNA synthesis, allowing acceptor invasions initiated earlier in the template to catch up with the primer terminus.

Differential susceptibility of HIV-1 reverse transcriptase to inhibition by RNA aptamers in enzymatic reactions monitoring specific steps during genome replication.

Nucleic acid aptamers to HIV-1 reverse transcriptase (RT) are potent inhibitors of DNA polymerase function in vitro, and they have been shown to inhibit viral replication when expressed in cultured T-lymphoid lines. We monitored RT inhibition by five RNA pseudoknot RNA aptamers in a series of biochemical assays designed to mimic discrete steps of viral reverse transcription. Our results demonstrate potent aptamer inhibition (IC50 values in the low nanomolar range) of all RT functions assayed, including RNA- and DNA-primed DNA polymerization, strand displacement synthesis, and polymerase-independent RNase H activity. Additionally, we observe differences in the time dependence of aptamer inhibition. Polymerase-independent RNase H activity is the most resistant to long term aptamer suppression, and RNA-dependent DNA polymerization is the most susceptible. Finally, when DNA polymerization was monitored in the presence of an RNA aptamer in combination with each of four different small molecule inhibitors, significant synergy was observed between the aptamer and the two nucleoside analog RT inhibitors (azidothymidine triphosphate or ddCTP), whereas two non-nucleoside analog RT inhibitors showed either weak synergy (efavirenz) or antagonism (nevirapine). Together, these results support a model wherein aptamers suppress viral replication by cumulative inhibition of RT at every stage of genome replication.

The K65R mutation in human immunodeficiency virus type 1 reverse transcriptase exhibits bidirectional phenotypic antagonism with thymidine analog mutations.

The K65R mutation in human immunodeficiency virus type 1 (HIV-1) reverse transcriptase (RT) is selected in vitro by many D-nucleoside analog RT inhibitors (NRTI) but has been rarely detected in treated patients. In recent clinical trials, the K65R mutation has emerged frequently in patients experiencing virologic failure on antiretroviral combinations that do not include 3'-azidothymidine (AZT). The reason for this change is uncertain. To gain insight, we examined trends in the frequency of K65R in a large genotype database, the association of K65R with thymidine analog mutations (TAMs) and other NRTI mutations, and the viral susceptibility profile of HIV-1 with K65R alone and in combination with TAMs. Among >60,000 clinical samples submitted for genotype analysis that contained one or more NRTI resistance mutations, the frequency of K65R increased from 0.4% in 1998 to 3.6% in 2003. Among samples with K65R, a strong negative association was evident with the TAMs M41L, D67N, L210W, T215Y/F, and K219Q/E (P<0.005) but not with other NRTI mutations, including the Q151M complex. This suggested that K65R and TAMs are antagonistic. To test this possibility, we generated recombinant HIV-1 encoding K65R in two different TAM backgrounds: M41L/L210W/T215Y and D67N/K70R/T215F/K219Q. K65R reduced AZT resistance from >50-fold to <2.5-fold in both backgrounds. In addition, TAMs antagonized the phenotypic effect of K65R, reducing resistance to tenofovir, abacavir, 2',3'-dideoxycytidine, dideoxyinosine, and stavudine. In conclusion, K65R and TAMs exhibit bidirectional phenotypic antagonism. This antagonism likely explains the negative association of these mutations in genotype databases, the rare emergence of K65R with antiretroviral therapies that contain AZT, and its more frequent emergence with combinations that exclude AZT.

Analysis of human immunodeficiency virus type 1 reverse transcriptase subunit structure/function in the context of infectious virions and human target cells.

The reverse transcriptase (RT) of all retroviruses is required for synthesis of the viral DNA genome. The human immunodeficiency virus type 1 (HIV-1) RT exists as a heterodimer made up of 51-kDa and 66-kDa subunits. The crystal structure and in vitro biochemical analyses indicate that the p66 subunit of RT is primarily responsible for the enzyme's polymerase and RNase H activities. Since both the p51 and p66 subunits are generated from the same coding region, as part of the Pr160(Gag-Pol) precursor protein, there are inherent limitations for studying subunit-specific function with intact provirus in a virologically relevant context. Our lab has recently described a novel system for studying the RT heterodimer (p51/p66) wherein a LTR-vpr-p51-IRES-p66 expression cassette provided in trans to an RT-deleted HIV-1 genome allows precise molecular analysis of the RT heterodimer. In this report, we describe in detail the specific approaches, alternative strategies, and pitfalls that may affect the application of this novel assay for analyzing RT subunit structure/function in infectious virions and human target cells. The ability to study HIV-1 RT subunit structure/function in a physiologically relevant context will advance our understanding of both RT and the process of reverse transcription. The study of antiretroviral drugs in a subunit-specific virologic context should provide new insights into drug resistance and viral fitness. Finally, we anticipate that this approach will help elucidate determinants that mediate p51-p66 subunit interactions, which is essential for structure-based drug design targeting RT heterodimerization.

Attenuation of DNA replication by HIV-1 reverse transcriptase near the central termination sequence.

Previous pre-steady-state kinetic studies of equine infectious anemia virus-1 (EIAV) reverse transcriptase (RT) showed two effects of DNA substrates containing the central termination sequence (CTS) on the polymerization reaction: reduction of burst amplitude in single nucleotide addition experiments and accumulation of termination products during processive DNA synthesis [Berdis, A. J., Stetor, S. R., Le Grice, S. F. J., and Barkley, M. D. (2001) Biochemistry 40, 12140-12149]. The present study of HIV RT uses pre-steady-state kinetic techniques to evaluate the molecular mechanisms of the lower burst amplitudes using both random sequence and CTS-containing DNA substrates. The effects of various factors, including primer/template length, binding orientation, and protein concentration, on the burst amplitude were determined using random sequence DNA substrates. The percent active RT increases with total RT concentration, indicating that reversible dissociation of RT dimer is responsible for substoichiometric burst amplitudes with normal substrates. This finding was confirmed by gel mobility shift assays. Like EIAV RT, HIV RT showed lower burst amplitudes on CTS-containing DNA substrates compared to random sequences. The dissociation kinetics of RT-DNA complexes were monitored by enzyme activity and fluorescence. Biphasic kinetics were observed for both random sequence and CTS-containing DNA complexes, revealing two forms of the RT-DNA complex. A mechanism is proposed to account for reduction in burst amplitude of CTS-containing DNA that is consistent with the results of both single nucleotide addition and dissociation experiments. The two forms of the RT-DNA complex may represent partitioning of primer/template between the P- and N-sites on RT for the nucleic acid substrate.

Protein evolution in viral quasispecies under selective pressure: a thermodynamic and phylogenetic analysis.

The evolution of RNA viruses under antiviral pressure is characterized by high mutation rates and strong selective forces that induce extremely rapid changes of protein sequences. This makes the course of molecular evolution directly observable on time scales of months. Here we study the interplay between selection for drug resistance and selection for thermodynamic stability in the protease (PR) and the reverse transcriptase (RT) of human immunodeficiency virus type 1 (HIV-1) clones extracted from two patients with complex treatment histories. This analysis shows that folding thermodynamic properties may fluctuate very strongly in the course of quasispecies evolution under selective pressure. For the first case, our data suggest that folding efficiency of the RT is sacrificed at the advantage of drug resistance, while the corresponding PR seems to undergo selection for thermodynamic stability in the absence of substitutions associated to resistance. The PR of the second case is not submitted to antiviral pressure during the period analyzed and seems to initiate random fluctuations that lead to the accidental increase of its folding efficiency. In summary, joint consideration of sequence evolution and thermodynamic parameters can represent a more comprehensive approach for the study of the evolution of RNA viruses.

Aminopyrimidinimino isatin analogues: design of novel non- nucleoside HIV-1 reverse transcriptase inhibitors with broad-spectrum chemotherapeutic properties.

PURPOSE: HIV is the most significant risk factor for many opportunistic infections such as tuberculosis, hepatitis, bacterial infections and others. In this paper, we describe an aminopyrimidinimino isatin lead compound as a novel non-nucleoside reverse transcriptase inhibitor with broad-spectrum chemotherapeutic properties for the effective treatment of AIDS and AIDS-related opportunistic infections. METHODS: The synthesis of various aminopyrimidinimino isatin derivatives was achieved in two steps and evaluated for anti-HIV, anti-HCV, antimycobacterial and antibacterial activities. RESULTS: Compound 1-cyclopropyl-6-fluoro-1,4-dihydro-4-oxo-7[[N4-[3'-(4'-amino-5'-trimethoxybenzylpyrimidin-2'-yl)imino-1'-isatinyl] methyl]N1-piperazinyl]-3-quinoline carboxylic acid (14) emerged as the most potent broad-spectrum chemotherapeutic agent active against HIV, HCV, M. tuberculosis and various pathogenic bacteria. Among the synthesized compounds compound 14 and 15 emerged as more promising broad-spectrum chemotherapeutic agents.

[Nucleotide-dependent degradation of nucleic acids by DNA and RNA polymerases]. / Nukeleotid-zavisimaia degradatsiia nukleinovykh kislot DNK- i RNK-polimerazami.

In this review we summarize the current knowledge about recently discovered reactions of nucleotide-dependent nucleic acid degradation catalyzed by DNA and RNA polymerases. These reactions consist in the excision of the 3'-nucleotide of nascent DNA or RNA chain in the presence of non-complementary r/dNTPs. In the case of DNA polymerases the dinucleoside-5',5"-tetraphosphate as a product of the reaction is formed. In contrast, in the case of RNA polymerases non-complementary r/dNTPs stimulate 3'-->5' exonuclease degradation of RNA transcript. The possible role of these reactions in fidelity of DNA and RNA synthesis, in resistance of HIV reverse transcriptase towards nucleoside inhibitors is discussed.

P53 in cytoplasm may enhance the accuracy of DNA synthesis by human immunodeficiency virus type 1 reverse transcriptase.

The tumor suppressor protein p53 displays 3' --> 5' exonuclease activity and can provide a proofreading function for DNA polymerases. Reverse transcriptase (RT) of human immunodeficiency virus (HIV)-1 is responsible for the conversion of the viral genomic ssRNA into the proviral DNA in the cytoplasm. The relatively low fidelity of HIV-1 RT was implicated as a dominant factor contributing to the genetic variability of the virus. The lack of intrinsic 3' --> 5' exonuclease activity, the formation of 3'-mispaired DNA and the subsequent extension of this DNA were shown to be determinants for the low fidelity of HIV-1 RT. It was of interest to analyse whether the cytoplasmic proteins may affect the accuracy of DNA synthesis by RT. We investigated the fidelity of DNA synthesis by HIV-1 RT with and without exonucleolytic proofreading provided by cytoplasmic fraction of LCC2 cells expressing high level of wild-type functional p53. Two basic features related to fidelity of DNA synthesis were studied: the misinsertion and mispair extension. The misincorporation of noncomplementary deoxynucleotides into nascent DNA and subsequent mispair extension by HIV-1 RT were substantially decreased in the presence of cytoplasmic fraction of LCC2 cells with both RNA/DNA and DNA/DNA template-primers with the same target sequence. The mispair extension frequencies obtained with the HIV-1 RT in the presence of cytoplasmic fraction of LCC2 cells were significantly lower (about 2.8-15-fold) than those detected with the purified enzyme. In addition, the productive interaction between polymerization (by HIV-1 RT) and exonuclease (by p53 in cytoplasm) activities was observed; p53 preferentially hydrolyses mispaired 3'-termini, permitting subsequent extension of the correctly paired 3'-terminus by HIV-1 RT. The data suggest that p53 in cytoplasm may affect the accuracy of DNA replication and the mutation spectra of HIV-1 RT by acting as an external proofreader. Furthermore, the decrease in error-prone DNA synthesis with RT in the presence of external exonuclease, provided by cytoplasmic p53, may partially account for lower mutation rate of HIV-1 observed in vivo.