Dynamics of HIV-1 recombination in its natural target cells

Levy, David; Aldrovandi, Grace M.; Kutsch, Olaf; Shaw, George M.

doi:10.1073/pnas.0306764101

Cited by 407 publications

(564 citation statements)

References 46 publications

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“…2d does not vanish but eventually rises again following predator-prey dynamics (9), so T* also has a late rise.] This overall two-phase dynamics is similar to the infected cell dynamics observed in in vitro experiments (2). With the overall dynamics thus qualitatively mimicking experiments, we employ this description to investigate the dynamics of multiple infections.…”

Section: Model Calculationssupporting

confidence: 58%

“…3 as parametric plots of T* i (t) vs. T* 1 (t). Recall that Levy et al (2) found that coinfected cells, presumably mostly T* 2 , are proportional to (T* 1 ) 2 . (Note that T* 2 Ͻ Ͻ T* 1 in their experiments except near peak infection so that T* 1 Ϸ T*.)…”

Section: Model Calculationsmentioning

confidence: 99%

“…multiple infection ͉ recombination ͉ scaling ͉ CD4 down-modulation ͉ mathematical model I n a significant shift from the prevalent paradigm of HIV infection that individual target cells are generally infected with single HIV virions, recent studies have demonstrated that multiple infections of cells occur far more frequently than single infections both in vivo (1,2) and in vitro (2)(3)(4). For instance, CD4 ϩ cells from the spleens of two HIV-infected individuals were found to harbor up to eight proviruses with three or four proviruses per cell on average (1).…”

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confidence: 99%

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HIV dynamics with multiple infections of target cells

Dixit

Perelson²

2005

Proc. Natl. Acad. Sci. U.S.A.

116

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The high incidence of multiple infections of cells by HIV sets the stage for rapid HIV evolution by means of recombination. Yet how HIV dynamics proceeds with multiple infections remains poorly understood. Here, we present a mathematical model that describes the dynamics of viral, target cell, and multiply infected cell subpopulations during HIV infection. Model calculations reproduce several experimental observations and provide key insights into the influence of multiple infections on HIV dynamics. We find that the experimentally observed scaling law, that the number of cells coinfected with two distinctly labeled viruses is proportional to the square of the total number of infected cells, can be generalized so that the number of triply infected cells is proportional to the cube of the number of infected cells, etc. Despite the expectation from Poisson statistics, we find that this scaling relationship only holds under certain conditions, which we predict. We also find that multiple infections do not influence viral dynamics when the rate of viral production from infected cells is independent of the number of times the cells are infected, a regime expected when viral production is limited by cellular rather than viral factors. This result may explain why extant models, which ignore multiple infections, successfully describe viral dynamics in HIV patients. Inhibiting CD4 down-modulation increases the average number of infections per cell. Consequently, altering CD4 down-modulation may allow for an experimental determination of whether viral or cellular factors limit viral production.multiple infection ͉ recombination ͉ scaling ͉ CD4 down-modulation ͉ mathematical model

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Section: Model Calculationssupporting

confidence: 58%

Section: Model Calculationsmentioning

confidence: 99%

mentioning

confidence: 99%

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HIV dynamics with multiple infections of target cells

Dixit

Perelson²

2005

Proc. Natl. Acad. Sci. U.S.A.

116

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“…Additionally, a recent study of the dynamics of HIV-1 recombination suggests that HIV-1 may have evolved high recombination rates to foster rapid diversification and further its survival (66).…”

Section: Implications For Evolutionmentioning

confidence: 99%

Evolvability is a selectable trait

Earl

Deem

2004

Proc. Natl. Acad. Sci. U.S.A.

202

165

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Concomitant with the evolution of biological diversity must have been the evolution of mechanisms that facilitate evolution, because of the essentially infinite complexity of protein sequence space. We describe how evolvability can be an object of Darwinian selection, emphasizing the collective nature of the process. We quantify our theory with computer simulations of protein evolution. These simulations demonstrate that rapid or dramatic environmental change leads to selection for greater evolvability. The selective pressure for large-scale genetic moves such as DNA exchange becomes increasingly strong as the environmental conditions become more uncertain. Our results demonstrate that evolvability is a selectable trait and allow for the explanation of a large body of experimental results.Darwin was obsessed with variation. His books, considered as an ensemble, devote much more attention to variation than to natural selection, because he knew that no satisfactory theory of evolutionary change could be constructed until the causes of variation and the empirical rule of its form and amount had been elucidated (1).

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“…Indeed, ex vivo experiments in HeLa CD4 ϩ -infected cells estimated that three events of template switching occur, on average, per replication cycle (16). Furthermore, it has recently been shown that the recombination rates are influenced by the type of cell infected, with the highest rates observed in macrophages (17). A crucial issue to address now is whether this high rate results from the presence of recombination hot spots interspersed among sequences yielding low recombination rates, or if it reflects a nearly constant frequency of strand transfer along the whole genome.…”

mentioning

confidence: 99%

The Structure of HIV-1 Genomic RNA in the gp120 Gene Determines a Recombination Hot Spot in Vivo

Galetto¹,

Moumen²,

Giacomoni³

et al. 2004

Journal of Biological Chemistry

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By frequently rearranging large regions of the genome, genetic recombination is a major determinant in the plasticity of the human immunodeficiency virus type I (HIV-1) population. In retroviruses, recombination mostly occurs by template switching during reverse transcription. The generation of retroviral vectors provides a means to study this process after a single cycle of infection of cells in culture. Using HIV-1-derived vectors, we present here the first characterization and estimate of the strength of a recombination hot spot in HIV-1 in vivo. In the hot spot region, located within the C2 portion of the gp120 envelope gene, the rate of recombination is up to ten times higher than in the surrounding regions. The hot region corresponds to a previously identified RNA hairpin structure. Although recombination breakpoints in vivo cluster in the top portion of the hairpin, the bias for template switching in this same region appears less marked in a cell-free system. By modulating the stability of this hairpin we were able to affect the local recombination rate both in vitro and in infected cells, indicating that the local folding of the genomic RNA is a major parameter in the recombination process. This characterization of reverse transcription products generated after a single cycle of infection provides insights in the understanding of the mechanism of recombination in vivo and suggests that specific regions of the genome might be prompted to yield different rates of evolution due to the presence of circumscribed recombination hot spots.

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Dynamics of HIV-1 recombination in its natural target cells

Cited by 407 publications

References 46 publications

HIV dynamics with multiple infections of target cells

HIV dynamics with multiple infections of target cells

Evolvability is a selectable trait

The Structure of HIV-1 Genomic RNA in the gp120 Gene Determines a Recombination Hot Spot in Vivo

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