The accuracy of reverse transcriptase from HIV-1

The impact of multidideoxynucleoside resistance-conferring mutations in human immunodeficiency virus type 1 reverse transcriptase on polymerase fidelity and error specificity

Variants of human immunodeficiency virus type 1 (HIV-1) that are highly resistant to a number of nucleoside analog drugs have been shown to develop in some patients receiving 2',3'-dideoxy-3'-azidothymidine therapy in combination with 2',3'-dideoxycytidine or 2',3'-dideoxyinosine. The appearance, in the reverse transcriptase (RT), of the Q151M mutation in such variants precedes the sequential appearance of three or four additional mutations, resulting in a highly resistant virus. Three of the affected residues are proposed to lie in the vicinity of the template-primer in the three-dimensional structure of the HIV-1 RT-double-stranded DNA complex. The amino acid residue Q151 is thought to be very near the templating base. The nucleoside analog resistance mutations in the beta9-beta10 (M184V) and the beta5a (E89G) strands of HIV-1 RT were previously shown to increase the fidelity of deoxynucleoside triphosphate insertion. Therefore, we have examined wild-type HIV-1BH10 RT and two nucleoside analog-resistant variants, the Q151M and A62V/V75I/F77L/F116Y/Q151M (VILYM) RTs, for their overall forward mutation rates in an M13 gapped-duplex assay that utilizes lacZ alpha as a reporter. The overall error rates for the wild-type, the Q151M, and the VILYM RTs were 4.5 x 10(-5), 4.0 x 10(-5), and 2.3 x 10(-5) per nucleotide, respectively. Although the mutant RTs displayed minimal decreases in the overall error rates compared to wild-type RT, the error specificities of both mutant RTs were altered. The Q151M RT mutant generated new hot spots, which were not observed for wild-type HIV-1 RT previously. The VILYM RT showed a marked reduction in error rate at two of the predominant mutational hot spots that have been observed for wild-type HIV-1 RT.

Variability analysis of HIV-1 gp120 V3 region: IV. Distribution functions for intra- and inter-subtype amino acid hamming distances

Distribution functions for intra- and inter- HIV-1 V3-loop subtypes amino acid Hamming distances were calculated (850 V3-loop sequences from the Los Alamos HIV-1 Database (1996) were used). These functions have pronounced bell-like shape. Such shapes of the histograms for HIV-1 V3 intra- and inter-subtype distriutions are discussed to confirm the applicability of different hierarchical cluster procedures for HIV-1 V3 classification. Two-mode distribution for the subtype E could sertificate that this subtype includes two thinner taxons.

Retroviral recombination is nonrandom and sequence dependent

Sequence variation plays a significant role in the pathogenesis and persistence of retroviral infections and is a major obstacle in the development of vaccines as well as therapies against lethal diseases caused by retroviruses. Recombination is one means by which sequence variation is generated. However, the basic molecular mechanisms of recombination are not adequately understood. In the present study, a spleen necrosis virus (SNV) recombination system was used to ask whether a known hot spot for mutation was also a hot spot for retroviral recombination. The system consisted of a pair of SNV vectors expressing two drug-resistance genes, constructed so that recombinants could be selected by a double resistant phenotype. Restriction enzyme site differences engineered into the vectors were used to map the location of recombination sites within relatively small intervals (55 to 420 bp). The vectors were modified to create two pairs that differed only by the presence of runs of identical nucleotides. The runs of identical nucleotides had been shown previously to be hot spots for frameshift mutations during SNV reverse transcription. Each vector pair was introduced into DSDh helper cells by infection. Viruses were harvested from doubly infected DSDh helper cells and used to infect D-17 target cells. Proviral sequences from 228 cell clones were analyzed by polymerase chain reaction and restriction enzyme digestion. Significant differences in the patterns of recombination were found between the two pairs of vectors. In particular, the frequency of recombination was higher than expected in the interval immediately following the runs. For both pairs of vectors, the overall pattern of recombination was nonrandom and one region was refractory toward recombination.

Insertions into the beta3-beta4 hairpin loop of HIV-1 reverse transcriptase reveal a role for fingers subdomain in processive polymerization

Human immunodeficiency virus type 1 (HIV-1) reverse transcriptase (RT) displays a characteristic poor processivity during DNA polymerization. Structural elements of RT that determine processivity are poorly understood. The three-dimensional structure of HIV-1 RT, which assumes a hand-like structure, shows that the fingers, palm, and thumb subdomains form the template-binding cleft and may be involved in determining the degree of processivity. To assess the influence of fingers subdomain of HIV-1 RT in polymerase processivity, two insertions were engineered in the beta3-beta4 hairpin of HIV-1NL4-3 RT. The recombinant mutant RTs, named FE20 and FE103, displayed wild type or near wild type levels of RNA-dependent DNA polymerase activity on all templates tested and wild type or near wild type-like sensitivities to dideoxy-NTPs. When polymerase activities were measured under conditions that allow a single cycle of DNA polymerization, both of the mutants displayed 25-30% greater processivity than wild type enzyme. Homology modeling the three-dimensional structures of wild type HIV-1NL4-3 RT and its finger insertion mutants revealed that the extended loop between the beta3 and beta4 strands protrudes into the cleft, reducing the distance between the fingers and thumb subdomains to approximately 12 A. Analysis of the models for the mutants suggests an extensive interaction between the protein and template-primer, which may reduce the degree of superstructure in the template-primer. Our data suggest that the beta3-beta4 hairpin of fingers subdomain is an important determinant of processive polymerization by HIV-1 RT.

Endogenous reverse transcriptase assays reveal synergy between combinations of the M184V and other drug resistance-conferring mutations in interactions with nucleoside analog triphosphates

Resistance of HIV-1 reverse transcriptase (RT) to nucleoside analogs (e.g. AZT, ddC and 3TC) is conferred by various amino acid substitutions or combinations thereof on the RT molecule. The M184V mutation, that confers high and low-level resistance to 3TC and ddC, respectively, can restore sensitivity to AZT when introduced into RT against a background of AZT-resistance. The K65R mutation, that confers low level resistance to both 3TC and ddC, can also restore sensitivity to AZT. This information is of potential utility in choosing combinations of anti-viral drugs for clinical use. To explore this subject further, we have used an endogenous RT reaction to study mutated viruses containing M184V alone or M184V combined with each of the K65R, E89G or both the M41L and T215Y substitutions. Endogenous assays possess the advantage of utilizing genomic RNA as template in a reaction mixture that includes each of tRNALys.3 and viral nucleocapsid protein, necessary for specific initiation of reverse transcription, as well as all other viral proteins that might impact on this process. We now show that viruses containing both M184V and K65R displayed synergistic resistance to 3TC triphosphate (3TCTP), while the same combination yielded the same level of resistance to ddC triphosphate (ddCTP) as that manifested by K65R alone. The combination of M184V and E89G displayed synergistic resistance against ddCTP but not 3TCTP, while viruses containing only E89G were highly resistant to 3TCTP and displayed low-level resistance to ddCTP. The results show that endogenous RT assays can reveal variable synergistic, antagonistic, or neutral effects in regard to drug sensitivity, depending on the presence of specific amino acid substitutions in RT itself.

DNA mismatch repair catalyzed by extracts of mitotic, postmitotic, and senescent Drosophila tissues and involvement of mei-9 gene function for full activity

Extracts of Drosophila embryos and adults have been found to catalyze highly efficient DNA mismatch repair, as well as repair of 1- and 5-bp loops. For mispairs T.G and G.G, repair is nick dependent and is specific for the nicked strand of heteroduplex DNA. In contrast, repair of A.A, C.A, G.A, C.T, T.T, and C.C is not nick dependent, suggesting the presence of glycosylase activities. For nick-dependent repair, the specific activity of embryo extracts was similar to that of extracts derived from the entirely postmitotic cells of young and senescent adults. Thus, DNA mismatch repair activity is expressed in Drosophila cells during both development and aging, suggesting that there may be a function or requirement for mismatch repair throughout the Drosophila life span. Nick-dependent repair was reduced in extracts of animals mutant for the mei-9 gene. mei-9 has been shown to be required in vivo for certain types of DNA mismatch repair, nucleotide excision repair (NER), and meiotic crossing over and is the Drosophila homolog of the yeast NER gene rad1.

Flexible positioning of the telomerase-associated nuclease leads to preferential elimination of nontelomeric DNA

In addition to a reverse transcriptase activity, telomerase is associated with a DNA endonuclease that removes nucleotides from a primer 3' terminus prior to telomere repeat addition. Here we examine the DNA specificity of the primer cleavage-elongation reaction carried out by the Euplotes crassus telomerase. We show that the primer cleavage activity copurified with the E. crassus telomerase polymerase, indicating that it either is an intrinsic property of telomerase or is catalyzed by a tightly associated factor. Using chimeric primers containing stretches of telomeric DNA that could be precisely positioned on the RNA template, we found that the cleavage site is more flexible than originally proposed. Primers harboring mismatches in dT tracts that aligned opposite nucleotides 37 to 40 in the RNA template were cleaved to eliminate the mismatched residues along with the adjacent 3' sequence. The cleaved product was then elongated to generate perfect telomeric repeats. Mismatches in dG tracts were not removed, implying that the nuclease does not track coordinately with the polymerase active site. Our data indicate that the telomerase-associated nuclease could provide a rudimentary proofreading function in telomere synthesis by eliminating mismatches between the DNA primer and the 5' region of the telomerase RNA template.

Lamivudine resistance of HIV type 1 does not delay development of resistance to nonnucleoside HIV type 1-specific reverse transcriptase inhibitors as compared with wild-type HIV type 1

We compared the development of resistance toward BI-RG-587 (nevirapine) and alpha-APA R89439 (loviride) starting from the wild-type HIV-1 strain IIIB and the 3TC-resistant HIV-1 strain containing the M184V mutation. The reverse transcriptase of the M184V mutant has been reported to have a higher fidelity. Our experiments showed that there was no significant delay in virus breakthrough of the M184V mutant as compared with the wild-type virus. We therefore conclude that the reported higher fidelity of the M184V mutant does not lead to a delay in the development of resistance to the nonnucleoside reverse transcriptase inhibitors nevirapine and loviride.

Drug susceptibility of subtypes A,B,C,D, and E human immunodeficiency virus type 1 primary isolates

We determined the susceptibility to antiviral drugs of clinical isolates of human immunodeficiency virus type 1 (HIV-1) subtypes A, B, C, D, and E. Isolates from treated and untreated patients were tested for sensitivity to zidovudine (ZDV), lamivudine (3TC), didanosine (ddI), nevirapine (NVP), foscarnet (PFA), and ritonavir (RNV). The susceptibility to these different drugs was broadly similar between the different subtypes of HIV-1. Isolates of subtype D showed a tendency toward slightly lower susceptibility to all the antiviral drugs, which could be related to the rapid growth characteristics of these isolates.

High fidelity of internal strand transfer catalyzed by human immunodeficiency virus reverse transcriptase

A system to study the fidelity of internal strand transfer events was constructed. A donor RNA, on which reverse transcriptase (RT)-directed DNA synthesis was initiated, shared homology with an acceptor RNA, to which DNAs initiated on the donor could transfer. The homology occurred over a 119-base internal region of the donor which coded for the N-terminal portion of the alpha-lac gene. Polymerase chain reaction (PCR) was used to amplify DNA synthesis products. The PCR products were then digested with PvuII and EcoRI and ligated into a vector which had this same region excised. Transformed Escherichia coli were screened for the ability to produce a functional beta-galactosidase protein by blue-white phenotype analysis with white colonies scored as those with errors in alpha-lac. Products synthesized on the donor were used to assess the error rate of human immunodeficiency virus-RT while products transferring to and subsequently extended on the acceptor (transfer products) were used to monitor transfer fidelity. Human immunodeficiency virus-RT made approximately 1 error per 7500 bases copied in the assay. Nucleocapsid protein (NCp), although stimulating strand transfer 3-fold, had no effect on RT fidelity. Transfer products in the absence of NCp had essentially the same amount of errors as donor-directed products while those produced with NCp showed a slight increase in error frequency. Overall, strand transfer events on this template were highly accurate. Since experiments with other templates have suggested that transfer is error prone, the fidelity of strand transfer may be highly sequence dependent.

Novel and dynamic evolution of equine infectious anemia virus genomic quasispecies associated with sequential disease cycles in an experimentally infected pony

We have investigated the genetic evolution of three functionally distinct regions of the equine infectious anemia virus (EIAV) genome (env, rev, and long terminal repeat) during recurring febrile episodes in a pony experimentally infected with a well-characterized reference biological clone designated EIAV(PV). Viral populations present in the plasma of an EIAV(PV)-infected pony during sequential febrile episodes (18, 34, 80, 106, and 337 days postinfection) were amplified from viral RNA, analyzed, and compared to the inoculated strain. The comparison of the viral quasispecies showed that the inoculated EIAV(PV) quasispecies were all represented during the first febrile episode, but entirely replaced at the time of the second febrile episode, and that new predominant quasispecies were associated with each subsequent cycle of disease. One of the more surprising results was the in vivo generation of large deletion (up to 15 amino acids) in the principal neutralizing domain (PND) of gp90 during the third febrile episode. This deletion did not alter the competence for in vitro replication as shown by the analysis of a env chimeric clone with a partially deleted PND and did not altered the fitness of the virus in vivo, since this partially deleted envelope became the major population during the fourth febrile episode. Finally, we showed that the amino acid mutations were not randomly distributed but delineated eight variables regions, V1 to V8, with V3 containing the PND region. These studies provide the first detailed description of the evolution of EIAV genomic quasispecies during persistent infection and reveal new insights into the genetics and potential mechanisms of lentivirus genomic variation.

HIV-1 acquires resistance to two classes of antiviral drugs through homologous recombination

Genetic recombination contributes to the genomic heterogeneity of human immunodeficiency virus type 1 (HIV-1). In the present study, we demonstrate that HIV-1 readily develops resistance to two classes of anti-HIV-1 drugs through in vitro genetic recombination involving large segments of the viral genome. Co-transfection of COS-7 cells with an HIV-1 plasmid (pSUM13) carrying five mutations in the reverse transcriptase (RT)-encoding region (A62V, V75I, F77L, F116Y, Q151M), conferring resistance to multiple dideoxynucleoside analogs (ddNs), and another HIV-1 plasmid (pSUM431) carrying five mutations in the protease-encoding region (V321, L33F, K451, 184V, L89M), conferring resistance to protease inhibitors such as KNI-272, readily produced HIV-1 carrying both sets of mutations when propagated in MT-2 cells in the presence of azidothymidine (AZT) and KNI-272. The resultant HIV-1 variant was highly resistant to both ddNs and KNI-272. Co-infection of MT-2 cells with HIV-1SUM13 carrying the RT mutations and HIV-1SUM431 carrying the mutations in the protease also generated HIV-1 with both sets of mutations when cultured with AZT and KNI-272. We also report here that the problematic artifactual recombination occurring during genetic analyses of heterogeneous nucleic acid sequences using polymerase chain reaction can be successfully obviated.

Higher fidelity of RNA-dependent DNA mispair extension by M184V drug-resistant than wild-type reverse transcriptase of human immunodeficiency virus type 1

Reverse transcriptase (RT) of human immunodeficiency virus type 1 (HIV-1) has low fidelity compared with RTs of other retroviruses and cellular DNA polymerases. We and others have previously found that the fidelity of DNA-dependent DNA polymerization (DDDP) of M184V-mutated HIV-1 RT is significantly higher than that of wild-type RT. Viruses containing the M184V substitution are highly resistant to (-)-2'-dideoxy-3'-thiacytidine (3TC) in vitro and in patients treated with 3TC monotherapy. It was of interest to determine the fidelity of RNA-dependent DNA polymerization (RDDP) of M184V RT compared with wild-type because this step occurs first in reverse transcription; errors made during this step may be copied in subsequent polymerization steps. Using an in vitro mispaired primer extension assay, M184V-mutated RT exhibited 3-49-fold decreased frequency of mispair extension compared with wild-type RT. Fidelity differences between M184V and wild-type RT were most marked in extension of A:G (49-fold) and A:C (16-fold) mispairs, with only a marginal (3-fold) decrease in the extension of A:A mispairs. RT containing a methionine to isoleucine (M184I) mutation showed only slight increases in RDDP fidelity compared with wild-type, ranging from 1.5- to 6-fold increases. Of the three RTs tested, wild-type RT was the most error-prone, with mispair extension frequencies ranging from 6.674 x 10(-1) to 7.454 x10(-2).

The fidelity of misinsertion and mispair extension throughout DNA synthesis exhibited by mutants of the reverse transcriptase of human immunodeficiency virus type 2 resistant to nucleoside analogs

The AIDS-causing retroviruses, human immunodeficiency virus types 1 and type 2 (HIV-1 and HIV-2, respectively) undergo extensive genetic variations, which effect their pathogenesis and resistance to drug therapy. It was postulated that this genetic hypervariability results from high rates of viral replication in conjugation with a relatively low fidelity of DNA synthesis [typical to the reverse transcriptases (RT) of these retroviruses]. As part of studying structure/function relationship in HIV RT, mutational analyses were conducted to identify amino acid residues which are involved in affecting the fidelity of DNA synthesis. The formation of 3'-mispaired DNA due to nucleotide misinsertions, and the subsequent elongation of this mismatched DNA were shown to be major determinants in affecting those substitutions during DNA synthesis (exhibited in vitro by HIV RT). It was interesting to find a correlation between sensitivity to nucleoside analogs (due to the ability to incorporate or reject an incoming analog) and the fidelity of DNA synthesis (which depends on the capacity to incorporate and extend a wrong nucleotide). Such a connection has already been found for several drug-resistant mutants of HIV-1 RT, with an increased fidelity of DNA synthesis relative to the wild-type RT. In the present study we have examined the fidelity of DNA synthesis using the same parameters of misinsertion and mispair extension for five novel drug-resistant mutants of HIV-2 RT; i.e. the single mutants [Val74]RT, [Gly89]RT and [Tyr215]RT and the double mutants [Val74,Tyr215]RT and [Gly89, Tyr215]RT. This comparative study suggests that unlike the Val74 mutant of HIV-1 RT, which was shown earlier to display a substantially enhanced fidelity, the comparable mutant of HIV-2 RT has fidelity similar to that of the wild-type RT. Depending on the assay employed and the DNA sequences extended, most other mutants of HIV-2 RT display moderate effects on the enzyme, leading to mild increases in fidelity of DNA synthesis. This implies a more complex and less distinctive correlation between drug-resistance, misinsertion and mispair extension in HIV-2 RT in contrast to HIV-1 RT, providing evidence for potential biochemical differences between these two related RT.

Determination of microbial diversity in environmental samples: pitfalls of PCR-based rRNA analysis

After nearly 10 years of PCR-based analysis of prokaryotic small-subunit ribosomal RNAs for ecological studies it seems necessary to summarize reported pitfalls of this approach which will most likely lead to an erroneous description on the microbial diversity of a given habitat. The following article will cover specific aspects of sample collection, cell lysis, nucleic acid extraction, PCR amplification, separation of amplified DNA, application of nucleic probes and data analysis.

Mutations of the HIV type 1 V3 loop under selection pressure with neutralizing monoclonal antibody NM-01

Variants of human immunodeficiency virus type 1 (HIV-1) were selected for resistance to the neutralizing monoclonal antibody (MAb) NM-01. MAb NM-01 recognizes the center of the third hypervariable domain (V3 loop) of the envelope gp120, and neutralizes diverse HIV-1 strains. In the continuous presence of MAb NM-01, transmission and propagation of molecularly cloned HIV-1 were performed in vitro to isolate escape variants. The polymerase chain reaction-single-strand conformation polymorphism and sequence analyses of these variants indicated that the antigenic change against MAb NM-01 is due to a single base substitution resulting in one amino acid interchange within the recognition site of MAb NM-01 in the V3 loop. Mutational analyses also demonstrated a nonrandom event of variability and the existence of mutational hot spots in the V3 loop. The bias of variability could be interpreted by the specificity of error-prone replication by HIV-1 reverse transcriptase. Furthermore, the results suggest that distribution of mutability might correlate closely with the stability of the secondary structure of RNA encoding the V3 loop region.

Slower evolution of human immunodeficiency virus type 1 quasispecies during progression to AIDS

The evolution of human immunodeficiency virus type 1 (HIV-1) quasispecies at the envelope gene was studied from the time of infection in 11 men who experienced different rates of CD4+ cell count decline and 6 men with unknown dates of infection by using DNA heteroduplex mobility assays. Quasispecies were genetically homogeneous near the time of seroconversion. Subsequently, slower proviral genetic diversification and higher plasma viremia correlated with rapid CD4+ cell count decline. Except for the fastest progressors to AIDS, highly diverse quasispecies developed in all subjects within 3 to 4 years. High quasispecies diversity was then maintained for years until again becoming more homogeneous in a subset of late-stage AIDS patients. Individuals who maintained high CD4+ cell counts showed continuous genetic turnover of their complex proviral quasispecies, while more closely related sets of variants were found in longitudinal samples of severely immunocompromised patients. The limited number of variants that grew out in short-term PBMC cocultures were rare in the uncultured proviral quasispecies of healthy, long-term infected individuals but more common in vivo in patients with low CD4+ cell counts. The slower evolution of HIV-1 observed during rapid progression to AIDS and in advanced patients may reflect ineffective host-mediated selection pressures on replicating quasispecies.

Variability analysis of HIV-1 gp120 V3 region: II. Hierarchy of taxons

In the previous work (M. Yu. Shchelkanov, A. N. Yudin, A. V. Antonov, N. S. Starikov, A. A. Vedenov, E. V. Karamov, J. Biomol. Struct. Dyn. 15, 217-229 (1997)) we have introduced the amino acid distribution function within HIV-1 taxons and Hamming-transformed Euclidean measures between their characteristics: consensus, subconsensus and sample mean. In this work the referred characteristics are used for hierarchical classification of amino acid sequences of gp120 V3 region belonging to different HIV-1 taxons. A comparative analysis of the results produced by various classification methods is carried out. Multidimensional scaling of distance matrix for the specified characteristics is used to visualize the pattern of HIV-1 variability.

The rapid spread of recombinants during a natural in vitro infection with two human immunodeficiency virus type 1 strains

We quantified a population of recombinants in a natural in vitro infection, using wild-type viruses without any pressure. It was found that recombinants emerged early after infection and constituted more than 20% of the whole proviral population 15 days after infection. Furthermore, recombinants were isolated as infectious viruses by simple limiting dilution. These results imply that, in addition to the high mutation rate of human immunodeficiency virus type 1 (HIV-1), recombination among HIV-1 strains plays a significant part in the development of the high diversity of HIV-1.

Antagonism of cytotoxic T lymphocyte-mediated lysis by natural HIV-1 altered peptide ligands requires simultaneous presentation of agonist and antagonist peptides

Mutations in human immunodeficiency virus (HIV) cluster in cytotoxic T lymphocyte (CTL) epitopes (Phillips, R. E. et al., Nature 1991. 354: 453) and are subject to immune-mediated positive selection (Price, D. A. et al., Proc. Natl. Acad. Sci. USA 1997. 94: 1890). We studied the effects of naturally occurring mutations in the HIV-1 p17 Gag HLA A2 restricted epitope SLYNTVATL on recognition by anti-HIV CTL. Most of these naturally occurring mutants escaped killing by one CTL line and the majority acted as CTL antagonists. We also investigated whether CTL exposed to a strict antagonist peptide restricted by HLA A2 were unresponsive when exposed to targets presenting the wild-type sequence. The results show that antagonism of anti-HIV CTL killing requires the simultaneous presence of agonist and antagonist peptide. We found no evidence that CTL exposed to an antagonist received a functionally negative signal since these CTL retained an unimpaired capacity to lyse targets bearing wild-type peptide.

Increased polymerase fidelity of the 3TC-resistant variants of HIV-1 reverse transcriptase

Human immunodeficiency virus type 1 (HIV-1) variants with resistance mutations in the reverse transcriptase (RT) gene appear during drug therapy with the nucleoside analogue 2',3'-dideoxy-3'-thiacytidine (3TC). These 3TC-resistant RT variants have a single point mutation that changes the 184Met residue into either Val or Ile. Both codon 184 variants are frequently observed in 3TC-treated patients and can also be selected in cell culture infections. We demonstrated previously that the 184Ile and 184Val RT enzymes exhibit a processivity defect in in vitro assays, with 184Ile being the least processive enzyme [Met(wt) >Val >Ile]. In this study, we measured the polymerase fidelity of the wild-type (184Met) and 3TC-resistant RT enzymes (184Ile and 184Val) on DNA and RNA templates. Both virion- extracted and Escherichia coli -expressed recombinant RT enzymes were used to measure the nucleotide misinsertion and mispair extension efficiencies. The 3TC-resistant enzymes were more accurate than the wild-type RT protein in both type of assays. The order of accuracy observed for the codon 184 variants [Ile >Val >Met(wt)] may suggest an inverse correlation between the fidelity and processivity properties of these enzymes.

Reverse transcriptase. The use of cloned Moloney murine leukemia virus reverse transcriptase to synthesize DNA from RNA

Reverse transcriptase (RT) is the key enzyme required for conversion of RNA to DNA. Cloning of Moloney murine leukemia virus (MMLV) RT has enable engineering an RT that lacks endogenous RNase H activity. RT catalyzes cDNA synthesis more efficiently in the absence of RNase H. We describe here a number of properties of MMLV RT and RNase H-minus MMLV RT not summarized in a single location elsewhere, providing a basis for best use of these enzymes in cDNA synthesis. In addition, general guidelines and detailed protocols are provided for use of MMLV RTs in one tube double-stranded cDNA synthesis, in [32P]cDNA synthesis, and in RT-PCR and long RT-PCR.

Use of single-cycle analysis to study rates and mechanisms of retroviral mutation

Retroviruses evolve at rapid rates. This allows them to escape immune surveillance, thwarts vaccine development, and leads to rapid emergence of drug-resistant virus. Information regarding the retroviral mutation rates and the underlying mechanisms of mutagenesis will undoubtedly expedite the development of strategies to combat retroviral-mediated diseases. In this review, we discuss how the unique retroviral life cycle can be adapted such that retroviral variation can be studied in a single cycle of replication. By limiting replication to a single cycle, retroviral mutation rates can be directly measured, and the consequences of mutations can be observed. In addition, retroviral recombination rates as well as the nature of primer strand transfer during reverse transcription can be studied using this system. Molecular analysis of the spectrum of mutations arising during a single cycle of virus replication also sheds light on the mechanisms of mutagenesis and retroviral replication.

In vivo dynamics of equine infectious anemia viruses emerging during febrile episodes: insertions/duplications at the principal neutralizing domain

Equine infectious anemia virus (EIAV) is a good model for studying mechanisms generating escaped retrovirus variants. We previously sequenced the entire gp90-encoding region of 22 cDNA clones obtained from five antigenically distinct isolates (F1V to F5V) recovered during febrile episodes in horse 493 experimentally infected with the Japanese virulent EIAV strain V70. The results showed that the mutations occurred in the principal neutralizing domain (PND) by insertions/duplications. In this study, we further characterized the PND of virus isolates sequentially recovered during 22 febrile episodes in seven horses newly infected with V70 or one of the V70-derived variants. Sequencing of 70 cDNA clones derived from the 22 episodes confirmed the generation of various new viral quasispecies with insertions/duplications in the PND. Although the insertion/duplication sequences in a total of 92 cDNA clones were extensively heterogeneous, we hypothesized that all the insertions/duplications occurred during reverse transcription from viral genomic RNA to minus strand DNA. The insertion/duplication regions were derived from a part of the PND sequence, which consisted of five small units. These small units, some with various substitutions and/or deletions, were also generated, especially in regions with insertions/duplications. Of particular note was that all these virus variants, except for two cDNA variants, were generated by essentially four different duplication pathways. Thus, these results extend the significance of insertions/duplications in the PND to the novel generation of EIAV in vivo during febrile episodes.

Gene therapy of T helper cells in HIV infection: mathematical model of the criteria for clinical effect

This paper presents a mathematical analysis of the criteria for gene therapy of T helper cells to have a clinical effect on HIV infection. The analysis indicates that for such a therapy to be successful, it must protect the transduced cells against HIV-induced death. The transduced cells will not survive as a population if the gene therapy only blocks the spread of virus from transduced cells that become infected. The analysis also suggests that the degree of protection against disease-related cell death provided by the gene therapy is more important than the fraction cells that is initially transduced. If only a small fraction of the cells can be transduced, transduction of T helper cells and transduction of haematopoietic progenitor cells will result in the same steady-state level of transduced T helper cells. For gene therapy to be efficient against HIV infection, our analysis suggests that a 100% protection against viral escape must be obtained. The study also suggests that a gene therapy against HIV infection should be designed to give the transduced cells a partial but not necessarily total protection against HIV-induced cell death, and to avoid the production of viral mutants insensitive to the gene therapy.

In vivo sequence variability of human immunodeficiency virus type 1 envelope gp120: association of V2 extension with slow disease progression

According to the rate of depletion of CD4 cell counts, we grouped 12 cases of human immunodeficiency virus type 1 (HIV-1) infection as 6 rapid (21.0 to 33.8 cells per microl per month) and 6 slow (0.9 to 7.9 cells per microl per month) progressors and determined the individual viral quasispecies patterns by sequencing the genome region encoding the V1, V2, and V3 loops of envelope protein. Although the quasispecies structures varied widely from one individual to another, a strong correlation was observed between a low rate of disease progression and a high degree of genetic diversity of HIV-1. Furthermore, the V2 loop extension was observed specifically in individuals with slow or no disease progression, whereas basic amino acid substitutions in V3 characteristic of a viral phenotype shift from non-syncytium inducing to syncytium inducing were observed in patients with advanced stages of disease regardless of their rate of disease progression. Studies with recombinant viruses suggested that elongation of V2 potentially restricts the capacity of HIV-1 to replicate in macrophages. Thus, our results suggest the association of distinct sequence features of both V3 and V2 with particular patterns of disease progression. Elongation of the V2 loop may be a good predictor of slow disease progression, while basic substitutions of V3 without elongation of V2 are characteristic of rapid progression.

The fidelity of 3' misinsertion and mispair extension during DNA synthesis exhibited by two drug-resistant mutants of the reverse transcriptase of human immunodeficiency virus type 1 with Leu74-->Val and Glu89-->Gly

The relatively low fidelity of DNA synthesis characteristic to the reverse transcriptases (RTs) of the AIDS-causing viruses, human immunodeficiency viruses types 1 and 2 (HIV-1 and HIV-2, respectively) was implicated as a dominant factor that contributes to the genetic hypervariability of these viruses. The formation of 3'-mispaired DNA and the subsequent extension of this DNA were shown to be key determinants that lead to the error proneness of these RTs. As part of our goal to study the structure/function relationship in HIV-1 RT, we have conducted mutational studies aimed at identifying amino-acid residues involved in affecting the fidelity of DNA synthesis by the enzyme. We have recently found that two mutants of HIV-1 RT, which show resistance to nucleoside analog inhibitors ([Leu184]RT and [Phe183]RT), exhibit in vitro error proneness of DNA synthesis lower than that of wild-type enzyme [Bakhanshvili, M., Avidan, O. & Hizi, A. (1996) Mutational studies of human immunodeficiency virus type 1 reverse transcriptase: the involvement of residues 183 and 184 in the fidelity of DNA synthesis, FEBS Lett. 391, 257-262]. Using both criteria, the current comparative study suggests that these two mutant RTs display a substantially enhanced fidelity of DNA synthesis relative to the wild-type RT counterpart. In the current study we have analyzed two additional drug-resistant mutants of HIV-1 RT, [Val74]RT and [Gly89]RT, for their in vitro fidelity of DNA synthesis using two parameters of DNA synthesis: 3' mispair formation and elongation of 3'-mismatched DNA. The current comparative study suggests that these two mutant RTs display a substantially enhanced fidelity of DNA synthesis relative to the wild-type RT counterpart, using both criteria. Analysis of the relative frequencies of misinsertion and mispair extension indicates that the overall error proneness of DNA synthesis in HIV-1 RT is wild-type > [Val74]RT > [Gly89]RT mutant. The results further support the possible linkage between the capacity of an enzyme to incorporate a nucleoside analog instead of the correct dNTP (leading to drug sensitivity) and the ability to incorporate and extend a wrong nucleotide (resulting in mutagenesis). Our results may bear on the potential use of selecting and maintaining HIV virions with high fidelity and drug-resistant RTs to suppress the subsequent appearance of virions resistant to other drugs.

The antiretrovirus drug 3'-azido-3'-deoxythymidine increases the retrovirus mutation rate

It was previously observed that the nucleoside analog 5-azacytidine increased the spleen necrosis virus (SNV) mutation rate 13-fold in one cycle of retrovirus replication (V. K. Pathak and H. M. Temin, J. Virol. 66:3093-3100, 1992). Based on this observation, we hypothesized that nucleoside analogs used as antiviral drugs may also increase retrovirus mutation rates. We sought to determine if 3'-azido-3'-deoxythymidine (AZT), the primary treatment for human immunodeficiency virus type 1 (HIV-1) infection, increases the retrovirus mutation rate. Two assays were used to determine the effects of AZT on retrovirus mutation rates. The strategy of the first assay involved measuring the in vivo rate of inactivation of the lacZ gene in one replication cycle of SNV- and murine leukemia virus-based retroviral vectors. We observed 7- and 10-fold increases in the SNV mutant frequency following treatment of target cells with 0.1 and 0.5 microM AZT, respectively. The murine leukemia virus mutant frequency increased two- and threefold following treatment of target cells with 0.5 and 1.0 microM AZT, respectively. The second assay used an SNV-based shuttle vector containing the lacZ alpha gene. Proviruses were recovered as plasmids in Escherichia coli, and the rate of inactivation of lacZ alpha was measured. The results indicated that treatment of target cells increased the overall mutation rate two- to threefold. DNA sequence analysis of mutant proviruses indicated that AZT increased both the deletion and substitution rates. These results suggest that AZT treatment of HIV-1 infection may increase the degree of viral variation and alter virus evolution or pathogenesis.

Pre-existence and emergence of drug resistance in HIV-1 infection

Antiviral treatment of HIV-1 infection often fails because of the rapid emergence of resistant virus within weeks of the start of therapy. This raises the question of whether resistant viruses pre-exist in drug-naive patients or whether it is produced after the start of therapy. Here we compare the likelihood of pre-existence with the likelihood of production of resistant virus during therapy. We show that provided resistant virus pre-exists, then a stronger therapy may lead to a greater initial reduction of virus load, but will also cause a faster rise of resistant virus. In this case the total benefit of treatment is independent of the degree of inhibition of sensitive virus. If, on the other hand, resistant mutants do not pre-exist, then the emergence of resistance during treatment depends on the efficacy of the drug. If the drug is sufficiently potent to eradicate sensitive virus, then the probability that resistant mutants first appear during therapy is smaller than the probability that they existed before therapy. If the drug cannot eradicate the sensitive virus, then after sufficiently long time resistant mutants will appear. However, mutants that are unlikely to pre-exist may taken long time to appear.

Possible roles of HIV-1 nucleocapsid protein in the specificity of proviral DNA synthesis and in its variability

Retroviral nucleocapsid (NC) protein is an integral part of the virion nucleocapsid where it coats the dimeric RNA genome. Due to its nucleic acid binding and annealing activities, NC protein directs the annealing of the tRNA primer to the primer binding site and greatly facilitates minus strand DNA elongation and transfer while protecting the nucleic acids against nuclease degradation. To understand the role of NCp7 in viral DNA synthesis, we examined the influence of NCp7 on self-primed versus primer-specific reverse transcription. The results show that HIV-1 NCp7 can extensively inhibit self-primed reverse transcription of viral and cellular RNAs while promoting primer-specific synthesis of proviral DNA. The role of NCp7 vis-a-vis the presence of mutations in the viral DNA during minus strand elongation was examined. NCp7 maximized the annealing between a cDNA(-) primer containing one to five consecutive errors and an RNA representing the 3' end of the genome. The ability of reverse transcriptase (RT) in the presence of NCp7 to subsequently extend the mutated primers depended upon the position of the mismatch within the primer:template complex. When the mutations were at the polymerisation site, primer extension by RT in the presence of NCp7 was very high, about 40% for one mismatch and 3% for five consecutive mismatches. Mutations within the DNA primer or at its 5' end had little effect on the extension of viral DNA by RT. Taken together these results indicate that NCp7 plays major roles in proviral DNA synthesis within the virion core due to its ability to promote prime-specific proviral DNA synthesis while concurrently inhibiting non-specific reverse transcription of viral and cellular RNAs. Moreover, the observation that NCp7 enhances the incorporation of mutations during minus strand DNA elongation favours the notion that NCp7 is a factor contributing to the high mutation rate of HIV-1.

Stereoisomers of deoxynucleoside 5'-triphosphates as substrates for template-dependent and -independent DNA polymerases

All four possible stereoisomers of dNTP with regard to deoxyribofuranose C-1' and C-4' carbon atoms were studied as substrates for several template-dependent DNA polymerases and template-independent terminal deoxynucleotidyl transferase. It was shown that DNA polymerases alpha, beta, and epsilon from human placenta and reverse transcriptases of human immunodeficiency virus and avian myeloblastosis virus incorporate into the DNA chain only natural beta-D-dNTPs, whereas calf thymus terminal deoxynucleotidyl transferase incorporates two nucleotide residues of alpha-D-dNTP and extends the resulting oligonucleotide in the presence of beta-D-dNTPs. The latter enzyme also extended alpha-anomeric D-oligodeoxynucleotide primers in the presence of beta-D-dNTPs. None of the studied enzymes utilized L-dNTPs. These data indicate that template-dependent DNA polymerases are highly stereospecific with regard to dNTPs, whereas template-independent terminal deoxynucleotidyl transferase shows less stereodifferentiation. It is likely that the active center of the latter enzyme forms no specific contacts with the nucleic bases of both nucleotide substrate and oligonucleotide primer.

Mispair extension fidelity of human immunodeficiency virus type 1 reverse transcriptases with amino acid substitutions affecting Tyr115

The role of Tyr115 of human immunodeficiency virus type 1 reverse transcriptase (HIV-1 RT) in the mispair extension fidelity of DNA dependent DNA synthesis was analysed by using a series of 15 mutant enzymes with substitutions at Tyr115. Their kinetic parameters for elongation using homopolymeric RNA-DNA and heteropolymeric DNA-DNA complexes showed major effects of the amino acid substitutions on the Km value for dNTP. Enzymes with large hydrophobic residues at position 115 displayed lower Km values than enzymes with small and charged amino acids at this position. The influence of all these amino acid replacements in mispair extension fidelity assays was analyzed using three different mismatches (A:C, A:G and A:A) at the 3'-terminal position of the primer DNA. For the A:C mispair, a 2. 6-33.4-fold increase in mispair extension efficiency (fext) was observed as compared with the wild-type enzyme. Unexpectedly, all the mutants tested as well as the wild-type RT were very efficient in extending the A:G and A:A transversion mispairs. This effect was due to the template-primer sequence context and not to the buffer conditions of the assay. The data support a role of Tyr115 in accommodating the complementary nucleotide into the nascent DNA while polymerization takes place.

Four Classes of HERV-K Long Terminal Repeats and Their Relative Promoter Strengths for Transcription

The human genome contains abundant copies of HERV-K endogenous retrovirus sequences. These remnants of ancient infection have the potential to reshape the genome by retrotransposition or infection since they are highly expressed in cells of germ line origin. When conserved nucleotide sequence variations in the U3 region of the HERV-K 3' LTR were used to distinguish between individual HERV-K proviruses, 4 major classes of HERV-K LTRs were identified. HERV-K U3 regions from the different classes were compared in an in vitro transcription assay and were found to vary significantly in their promoter activities. Copyright 1997 S. Karger AG, Basel

Incorporation of the guanosine triphosphate analogs 8-oxo-dGTP and 8-NH2-dGTP by reverse transcriptases and mammalian DNA polymerases

We have measured the efficiencies of utilization of 8-oxo-dGTP and 8-NH2-dGTP by human immunodeficiency virus type 1 and murine leukemia virus reverse transcriptases and compared them to those of DNA polymerases alpha and beta. Initially, we carried out primer extension reactions in the presence of dGTP or a dGTP analog and the remaining three dNTPs using synthetic DNA and RNA templates. These assays revealed that, in general, 8-NH2-dGTP is incorporated and extended more efficiently than 8-oxo-dGTP by all enzymes tested. Second, we determined rate constants for the incorporation of each analog opposite a template cytidine residue using steady state single nucleotide extension kinetics. Our results demonstrated the following. 1) Both reverse transcriptases incorporate the nucleotide analogs; discrimination against their incorporation is a function primarily of Km or Vmax depending on the analog and the enzyme. 2) Discrimination against the analogs is more stringent with the DNA template than with a homologous RNA template. 3) Polymerase alpha exhibits a mixed kinetic phenotype, with a large discrimination against 8-oxo-dGTP but a comparatively higher preference for 8-NH2-dGTP. 4) Polymerase beta incorporates both analogs efficiently; there is no discrimination with respect to Km and a significantly lower discrimination with respect to Vmax when compared with the other polymerases.

Differential tolerance to DNA polymerization by HIV-1 reverse transcriptase on N6 adenine C10R and C10S benzo[a]pyrene-7,8-dihydrodiol 9,10-epoxide-adducted templates

To determine the effect of various stereoisomers of benzo[a]pyrene-7,8-dihydrodiol 9,10-epoxide (BPDE) on translesion bypass by human immunodeficiency virus-1 reverse transcriptase and its alpha-helix H mutants, six 33-mer templates were constructed bearing site- and stereospecific adducts. This in vitro model system was chosen to understand the structure-function relationships between the polymerase and damaged DNA during replication. Comparison of the replication pattern between wild type human immunodeficiency virus-1 reverse transcriptase and its mutants, using primers which were 3' to the lesion, revealed essentially similar patterns. While these primers terminated with all three of the C10R and two of the C10S BPDE-adducted templates 1 base 5' and 1 base 3' to the damaged site respectively, (+)-anti-trans-(C10S) BPDE-adducted DNA alone permitted the formation of full-length products. Utilization of a primer with its 3'-hydroxyl 1 base beyond the lesion resulted in full-length products with all the C10S BPDE-adducted templates and the (-)-syn-trans-(C10R)-BPDE-adducted template, following replication with either the wild type or mutant enzymes. However, the other two C10R BPDE-adducted templates failed to allow any primer extension, even with the wild type enzyme. Although T.P depletion studies further confirmed the differential primer extension abilities using the C10R and C10S adducted templates, their binding affinities were similar, yet distinct from the unadducted template.

Evolutionary mechanisms and population dynamics of the third variable envelope region of HIV within single hosts

Clonal diversifications of HIV virus were monitored by periodic samplings on each of the six patients with regard to 183- to 335-bp segments of the env gene, which invariably included the functionally critical V3 region. Subsequently, six individual phylogenetic trees of viral variants were constructed. It was found that at one time or another during the course of disease progression, viral variants were inexplicably released from a strong negative selection against nonsynonymous base substitutions, possibly indicating positive selection. This resulted in concentrated amino acid substitutions at five specific sites within the V3 region. It was noted that these sites were often involved as antigenic determinants that provoked the host immune response and that these sites were also involved in the determination of viral phenotypes as to their cell tropism, syncytium formation capability, and replication rates.

Human immunodeficiency virus type 1 molecular evolution and the measure of selection

Human immunodeficiency virus (HIV) envelope genes are highly variable between and often within individuals. Part of this variability is thought to be the result of immune-mediated positive selection for sequence diversity. To measure positive selection it has become customary in HIV research to calculate the ratio of the proportions of synonymous (ds) and nonsynonymous (dn) substitutions per potential synonymous or nonsynonymous site, respectively. However, another measure that can be used is the difference between ds and dn, delta d. We show, by example, that using the ratio, ds/dn, or the difference, delta d, may lead us to different conclusions regarding the existence of positive selection pressure. We conclude by noting that until we understand the processes that mediate nucleotide variation in a host selective environment, inferences based on summary statistics characterizing types of nucleotide substitutions should be made with caution.

Retroviral mutation rates and A-to-G hypermutations during different stages of retroviral replication

Retroviruses mutate at a high rate in vivo during viral replication. Mutations may occur during proviral transcription by RNA polymerase II, during minus-strand DNA synthesis (RNA template) by viral reverse transcriptase, or during plus-strand DNA synthesis (DNA template) by reverse transcriptase. To determine the contributions of different stages of replication to the retroviral mutation rates, we developed a spleen necrosis virus-based in vivo system to selectively identify mutations occurring during the early stage (RNA transcription plus minus-strand synthesis) and the late stage (plus-strand synthesis plus DNA repair). A lacZalpha reporter gene was inserted into the long terminal repeat (LTR) of a spleen necrosis virus shuttle vector, and proviruses were recovered from infected cells as plasmids containing either one or both LTRs. Plasmids containing both LTRs generated a mutant phenotype only if the lacZalpha genes in both LTRs were mutated, which is most likely to occur during the early stage. Mutant phenotypes were identified from plasmids containing one LTR regardless of the stage at which the mutations occurred. Thus, mutant frequencies obtained after recovery of plasmids containing both LTRs or one LTR provided early-stage and total mutation rates, respectively. Analysis of 56,409 proviruses suggested that the retroviral mutation rates during the early and late stages of replication were equal or within twofold of each other. In addition, two mutants with A-to-G hypermutations were discovered, suggesting a role for mammalian double-stranded RNA adenosine deaminase enzyme in retroviral mutations. These experiments provide a system to selectively identify mutations in the early stage of retroviral replication and to provide upper and lower limits to the in vivo mutation rates during minus-strand and plus-strand synthesis, respectively.

Misincorporation by HIV-1 reverse transcriptase promotes recombination via strand transfer synthesis

Genome heterogeneity in retroviruses derives from poor fidelity of the reverse transcriptase (RT) and recombination via RT-catalyzed strand transfer synthesis. RTs lack proofreading ability, and they proficiently extend primers with mismatched termini. Recombination reactions carried out in vitro are accompanied by a high frequency of base substitution errors, suggesting a relationship. Here we provide evidence that misincorporation during RNA-directed DNA synthesis promotes strand transfer recombination. Experiments involved measurement of DNA synthesis, RNase H-directed cleavage, and strand transfer synthesis from preformed mismatched primers on RNA templates by human immunodeficiency virus (HIV) RT in vitro. A significant pause in synthesis occurred from a G(primer). rA(template) mismatch compared to the synthesis from a correctly paired (T.A) primer. The misincorporation-induced pause allowed an unusually large area of RT-RNase H-directed cleavage of the template RNA beneath the primer. Strand transfer to an acceptor molecule with sequence identical to the template RNA was about 50% more efficient than if the primer had had a correctly paired terminus. Overall transfer was measured over a large region of homology. Assuming that enhanced transfer occurs primarily at the site of the mismatch, the actual increase in transfer at that site must have been 1-2 orders of magnitude. Inclusion of a different acceptor molecule with complete complementarity to the originally mismatched 3' primer terminus resulted in an additional 2-fold increase in strand transfer efficiency. Overall, these results suggest the mechanism by which misincorporation during minus strand DNA synthesis in retroviral replication would promote high frequency recombination.

Mutational studies of human immunodeficiency virus type 1 reverse transcriptase: the involvement of residues 183 and 184 in the fidelity of DNA synthesis

The high error rates characteristic of human immunodeficiency virus type-1 reverse transcriptase (HIV-1 RT) are a presumptive source of the viral hypermutability that impedes prevention and therapy of acquired immunodeficiency syndrome (AIDS). We have analyzed two mutants of HIV-1 RT by conducting a comparative study of the accuracy of DNA synthesis. Each mutant bears a single amino acid substitution adjacent to the two aspartic acid residues at positions 185 and 186 in the highly conserved DNA polymerase active site. The first mutant, Met 184-->Leu (M184L), displays a marked reduction in both misinsertion and mispair extension, suggesting a fidelity of DNA synthesis significantly higher than that of the wild-type HIV-1 RT. The second mutant, Tyr 183-->Phe (Y183F), shows a decrease in mispair extension with no significant change in misincorporation. Thus, the overall pattern of error-proneness of DNA synthesis is: wild-type HIV-1 RT > Y183F > M184L. Taken together, it is possible that residues 183 and 184 contribute to the low fidelity of DNA synthesis characteristic of the reverse transcriptases of HIV-1, HIV-2 and possibly, of other lentiviruses. Our observations may bear on the nature of potential mutations responsible for resistance to the nucleoside analogs used in chemotherapy of AIDS.

Strand transfer is enhanced by mismatched nucleotides at the 3' primer terminus: a possible link between HIV reverse transcriptase fidelity and recombination

Strand transfer catalyzed by HIV reverse transcriptase (RT) was examined. The system consisted of a 142 nt RNA (donor) to which a 50 nt DNA primer was hybridized. The primer bound such that its 3' terminal nucleotide hybridized to the 12th nt from the 5' end of the donor. The 3' terminal nucleotide on the primer was either a G, A or T residue. Since the corresponding nucleotide of the donor was a C, the G formed a matched terminus and the A or T a mismatched terminus. The efficiency with which DNA bound to the donor transferred to a second RNA, termed acceptor, was monitored. The acceptor was homologous to the donor for all but the last 9 nt at the 5' end of the donor. Therefore, homologous strand transfer could occur at any point prior to the DNA being extended into the nonhomologous region on the donor. Strand transfer occurred approximately twice as efficiently with the mismatched versus matched substrates. The mismatched nucleotide was fixed into transfer products indicating that excision of the mismatch was not required for RT extension or transfer. Results suggest that base misincorporations by RT may promote recombination by enhancing strand transfer.

Replication infidelity during a single cycle of Ty1 retrotransposition

Retroviruses undergo a high frequency of genetic alterations during the process of copying their RNA genomes. However, little is known about the replication fidelity of other elements that transpose via reverse transcription of an RNA intermediate. The complete sequence of 29 independently integrated copies of the yeast retrotransposon Ty1 (173,043 nt) was determined, and the mutation rate during a single cycle of replication was calculated. The observed base substitution rate of 2.5 x 10(-5) bp per replication cycle suggests that this intracellular element can mutate as rapidly as retroviruses. The pattern and distribution of errors in the Ty1 genome is nonrandom and provides clues to potential in vivo molecular mechanisms of reverse transcriptase-mediated error generation, including heterogeneous RNase H cleavage of Ty1 RNA, addition of terminal nontemplated bases, and transient dislocation and realignment of primer-templates. Overall, analysis of errors generated during Ty1 replication underscores the utility of a genetically tractable model system for the study of reverse transcriptase fidelity.

Increased polymerase fidelity of E89G, a nucleoside analog-resistant variant of human immunodeficiency virus type 1 reverse transcriptase

Nucleoside analog resistance in human immunodeficiency virus type 1 results from mutations in reverse transcriptase (RT) that allow the enzyme to discriminate against such analogs. To evaluate the possible impact of such mutations on the ability of human immunodeficiency virus RT to selectively incorporate Watson-Crick base-paired deoxynucleotide triphosphates (dNTPs) over incorrectly paired dNTPs, we have measured the fidelity of dNTP insertion by the E89G variant of RT in in vitro reaction mixtures containing synthetic template primers. The E89G RT was previously shown to be resistant to several ddNTPs and to phosphonoformic acid. Our results show that the mutant enzyme displays a lower level of efficiency of misinsertion than did the wild-type RT for every mispair tested (ranging from 2- to 17-fold.

Cyclophilin A is required for the replication of group M human immunodeficiency virus type 1 (HIV-1) and simian immunodeficiency virus SIV(CPZ)GAB but not group O HIV-1 or other primate immunodeficiency viruses

The human immunodeficiency virus type 1 (HIV-1) Gag polyprotein binds to cyclophilin A and incorporates this cellular peptidyl prolyl-isomerase into virions. Disruption of cyclophilin A incorporation, either by gag mutations or by cyclosporine A, inhibits virion infectivity, indicating that cyclophilin A plays an essential role in the HIV-1 life cycle. Using assays for packaging of cyclophilin A into virions and for viral replication sensitivity to cyclosporine A, as well as information gleaned from the alignment of Gag residues encoded by representative viral isolates, we demonstrate that of the five lineages of primate immunodeficiency viruses, only HIV-1 requires cyclophilin A for replication. Cloned viral isolates from clades A, B, and D of HIV-1 group M, as well as a phylogenetically related isolate from chimpanzee, all require cyclophilin A for replication. In contrast, the replication of two outlier (group O) HIV-1 isolates is unaffected by concentrations of cyclosporine A which disrupt cyclophilin A incorporation into virions, indicating that these viruses are capable of replicating independently of cyclophilin A. These studies identify the first phenotypic difference between HIV-1 group M and group O and are consistent with phylogenetic studies suggesting that the two HIV-1 groups were introduced into human populations via separate zoonotic transmission events.