Recombination occurs at a high rate in retroviral replication, and its observation requires a virion containing two different RNA molecules (heterodimeric particles). Analysis of retroviral recombinants formed after a single round of replication revealed that (i) the nonselected markers changed more frequently than expected from the rate of recombination of selected markers; (ii) the transfer of the initially synthesized minus strand strong stop DNA was either intramolecular or intermolecular; (iii) the transfer of the first synthesized plus strand strong stop DNA was always intramolecular; and (iv) there was a strong correlation between the type of transfer of the minus strand strong stop DNA and the number of template switches observed. These data suggest that retroviral recombination is ordered and occurs during the synthesis of both minus and plus strand DNA.
HIV-1 capsid core disassembly (uncoating) must occur before integration of viral genomic DNA into the host chromosomes, yet remarkably, the timing and cellular location of uncoating is unknown. Previous studies have proposed that intact viral cores are too large to fit through nuclear pores and uncoating occurs in the cytoplasm in coordination with reverse transcription or at the nuclear envelope during nuclear import. The capsid protein (CA) content of the infectious viral cores is not well defined because methods for directly labeling and quantifying the CA in viral cores have been unavailable. In addition, it has been difficult to identify the infectious virions because only one of ∼50 virions in infected cells leads to productive infection. Here, we developed methods to analyze HIV-1 uncoating by direct labeling of CA with GFP and to identify infectious virions by tracking viral cores in living infected cells through viral DNA integration and proviral DNA transcription. Astonishingly, our results show that intact (or nearly intact) viral cores enter the nucleus through a mechanism involving interactions with host protein cleavage and polyadenylation specificity factor 6 (CPSF6), complete reverse transcription in the nucleus before uncoating, and uncoat <1.5 h before integration near (<1.5 μm) their genomic integration sites. These results fundamentally change our current understanding of HIV-1 postentry replication events including mechanisms of nuclear import, uncoating, reverse transcription, integration, and evasion of innate immunity.
Retroviruses contain two complete viral genomic RNAs in each virion. A system to study in a single round ofreplication the products of virions with two different genomic RNAs was established. A spleen necrosis virus-based splicing vector containing both the neomycin-resistance gene (neo) and the hygromycin B phosphotransferase gene (hygro) was used. Two frameshift mutants were derived from this vector such that the neo and the hygro genes were inactivated in separate vectors. Thus, each vector confers resistance to only one selection. The vectors with frameshift mutations were separately propagated and were pooled to infect DSDh helper cells. Doubly resistant cell clones were isolated, and viruses produced from these clones were used to infect D17 cells. This protocol allowed virions containing two different genomic RNAs (heterozygotes) to complete one round ofretroviral replication. The molecular nature of progeny that conferred resistance to single or double selection and their ratio were determined. Our data demonstrate that each infectious heterozygous virion produces only one provirus. The rate of retroviral recombination is =2% per kilobase per replication cycle. Recombinant proviruses are progeny of heterozygous virions.The retroviral life cycle requires DNA molecules to be copied from viral RNA and to integrate into the host genome to form the provirus (1). However, a unique feature of retroviruses is that two RNA genomes are packaged in one virion (2-7). It has been suggested that one provirus is formed from the two copies ofgenomic RNA in one virion; that is, retroviruses are pseudodiploids (8,9). Others have suggested that more than one copy of the provirus can be formed from one infectious event (10). Retroviruses have also been observed to undergo frequent genetic recombination (11)(12)(13)(14)(15)(16) MATERIALS AND METHODS Definitions. One round of replication is defined as beginning with a provirus in one cell and ending with the formation of a provirus in another cell. Thus, the events in one round of replication include RNA transcription of the proviral DNA, assembly of the virus, entry of virus into a host cell, reverse transcription of the genome, and integration. Rate refers to the frequency of events -occurring in one round of replication. Rate ofrecombination is calculated by comparing the titer of doubly resistant colonies (recombinant phenotype) with the lower titer of the two types of singly resistant colonies (parental phenotypes). The titers of the doubly resistant colonies were determined from the linear range of a series of 10-fold dilutions.Plasmid Construction. pWH12, pWH13, and pWH14 were derived from pJD216NeoHy (17). pJD216NeoHy was partially digested with Nco I, and the resulting recessed 3' ends were filled in by the Klenow fragment of Escherichia coli DNA polymerase I. These products were ligated and were used to transform competent E. coli cells. This approach resulted in two plasmids, pWH13 and pWH14. Each contained a 4-base pair (bp) insertion in either the neo (pW...
A long-standing question in retrovirus biology is how RNA genomes are distributed among virions. In the studies presented in this report, we addressed this issue by directly examining HIV-1 RNAs in virions using a modified HIV-1 genome that contained recognition sites for BglG, an antitermination protein in the Escherichia coli bgl operon, which was coexpressed with a fragment of BglG RNA binding protein fused to a fluorescent protein. Our results demonstrate that the majority of virions (>90%) contain viral RNAs. We also coexpressed HIV-1 genomes containing binding sites for BglG or the bacteriophage MS2 coat protein along with 2 fluorescent protein-tagged RNA binding proteins. This method allows simultaneously labeling and discrimination of 2 different RNAs at single-RNA-detection sensitivity. Using this strategy, we obtained physical evidence that virions contain RNAs derived from different parental viruses (heterozygous virion) at ratios expected from a random distribution, and we found that this ratio can be altered by changing the dimerization sequences. Our studies of heterozygous virions also support a generally accepted but unproven assumption that most particles contain 1 dimer. This study provides answers to long-standing questions in HIV-1 biology and illustrates the power and sensitivity of the 2-RNA labeling method, which can also be adapted to analyze various issues of RNA biogenesis including the detection of different RNAs in live cell imaging.Bgl ͉ MS2 ͉ dimerization ͉ DIS ͉ fluorescent protein
Reverse transcription and integration are the defining features of the Retroviridae; the common name "retrovirus" derives from the fact that these viruses use a virally encoded enzyme, reverse transcriptase (RT), to convert their RNA genomes into DNA. Reverse transcription is an essential step in retroviral replication. This article presents an overview of reverse transcription, briefly describes the structure and function of RT, provides an introduction to some of the cellular and viral factors that can affect reverse transcription, and discusses fidelity and recombination, two processes in which reverse transcription plays an important role. In keeping with the theme of the collection, the emphasis is on HIV-1 and HIV-1 RT. I t has been 40 years since the discovery of reverse transcriptase (RT) was announced by Howard Temin and David Baltimore, who independently showed that retroviral virions contain an enzymatic activity that can copy RNA into DNA (Baltimore 1970;Mizutani et al. 1970). These experiments provided the crucial proof of Temin's provirus hypothesis that retroviral infections persist because the RNA genome found in the virions is converted into DNA (Temin 1964). The sequences of the genomes of eukaryotes show how pervasive reverse transcription is in nature; not only do these genomes contain large numbers of endogenous retroviruses, but also a variety of retroposons and reverse-transcribed elements. The discovery in the early 1980s, that AIDS is caused by a human retrovirus, HIV-1, invigorated retroviral research and focused attention on the viral enzymes, which have become the primary target of anti-AIDS drugs. Not surprisingly, the focus of RT research shifted from the RTs of the murine leukemia viruses (MLV) and the avian myeloblastosis virus to HIV-1 RT. The first approved anti-HIV drug, AZT, targets RT, and of the 26 drugs currently approved to treat HIV-1 infections, 14 are RT inhibitors. In addition, RTs ( primarily recombinant MLV RTs) have become extremely valuable tools that are widely used in research, in clinical/diagnostic tests, and in biotechnology. We provide here a relatively brief description of the process of reverse transcription, the structure and biochemical functions of RT, some information about how other viral and cellular factors influence reverse transcription, and briefly consider how the reverse transcription process affects both the mutations that arise during
Neither the number of HIV-1 proviruses within individual infected cells in HIV-1–infected patients nor their genetic relatedness within individual infected cells and between cells and plasma virus are well defined. To address these issues we developed a technique to quantify and genetically characterize HIV-1 DNA from single infected cells in vivo. Analysis of peripheral blood CD4 + T cells from nine patients revealed that the majority of infected cells contain only one copy of HIV-1 DNA, implying a limited potential for recombination in virus produced by these cells. The genetic similarity between HIV populations in CD4 + T cells and plasma implies ongoing exchange between these compartments both early and late after infection.
Recombination is a major mechanism that generates variation in populations of human immunodeficiency virus type 1 (HIV-1). Mutations that confer replication advantages, such as drug resistance, often cluster within regions of the HIV-1 genome. To explore how efficiently HIV-1 can assort markers separated by short distances, we developed a flow cytometry-based system to study recombination. Two HIV-1-based vectors were generated, one encoding the mouse heat-stable antigen gene and green fluorescent protein gene (GFP), and the other encoding the mouse Thy-1 gene and GFP. We generated derivatives of both vectors that contained nonfunctional GFP inactivated by different mutations. Recombination in the region between the two inactivating mutations during reverse transcription could yield a functional GFP. With this system, we determined that the recombination rates of markers separated by 588, 300, 288, and 103 bp in one round of viral replication are 56, 38, 31, and 12%, respectively, of the theoretical maximum measurable recombination rate. Statistical analyses revealed that at these intervals, recombination rates and marker distances have a near-linear relationship that is part of an overall quadratic fit. Additionally, we examined the segregation of three markers within 600 bp and concluded that HIV-1 crossover events do not exhibit high negative interference. We also examined the effects of target cells and viral accessory proteins on recombination rate. Similar recombination rates were observed when human primary CD4؉ T cells and a human T-cell line were used as target cells. We also found equivalent recombination rates in the presence and absence of accessory genes vif, vpr, vpu, and nef. These results illustrate the power of recombination in generating viral population variation and predict the rapid assortment of mutations in the HIV-1 genome in infected individuals.
Recent studies have shown that APOBEC3G (A3G), a potent inhibitor of human immunodeficiency virus type 1 (HIV-1) replication, is localized to cytoplasmic mRNA-processing bodies (P bodies). However, the functional relevance of A3G colocalization with P body marker proteins has not been established. To explore the relationship between HIV-1, A3G, and P bodies, we analyzed the effects of overexpression of P body marker proteins Mov10, DCP1a, and DCP2 on HIV-1 replication. Our results show that overexpression of Mov10, a putative RNA helicase that was previously reported to belong to the DExD superfamily and was recently reported to belong to the Upf1-like group of helicases, but not the decapping enzymes DCP1a and DCP2, leads to potent inhibition of HIV-1 replication at multiple stages. Mov10 overexpression in the virus producer cells resulted in reductions in the steady-state levels of the HIV-1 Gag protein and virus production; Mov10 was efficiently incorporated into virions and reduced virus infectivity, in part by inhibiting reverse transcription. In addition, A3G and Mov10 overexpression reduced proteolytic processing of HIV-1 Gag. The inhibitory effects of A3G and Mov10 were additive, implying a lack of functional interaction between the two inhibitors. Small interfering RNA (siRNA)-mediated knockdown of endogenous Mov10 by 80% resulted in a 2-fold reduction in virus production but no discernible impact on the infectivity of the viruses after normalization for the p24 input, suggesting that endogenous Mov10 was not required for viral infectivity. Overall, these results show that Mov10 can potently inhibit HIV-1 replication at multiple stages.
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