Modeling viral coevolution: HIV multi-clonal persistence and competition dynamics

Bagnoli, Franco; Lió, Píetro; Sguanci, Luca

doi:10.1016/j.physa.2005.10.055

Cited by 13 publications

(23 citation statements)

References 46 publications

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“…To illustrate the theoretical results, we select K = 10 12 , γ 1 = 5 × 10 −6 , γ 2 = 10 −5 , γ 3 = 5 × 10 −6 , δ 1 = 0.08, δ 2 = 0.9, β = 9 × 10 −7 , c = 2.3, N = 100 from [1,2,6,48]. When λ = 10 5 or λ = 1000, we have B < 0 and (C1) holds.…”

Section: Backward Bifurcations From Ifementioning

confidence: 99%

“…Let us illustrate interesting phenomena from this type of bifurcations. We take K = 10 12 , γ 2 = 10 −5 , c = 2.3 from [1,2,6,48] and fix γ 3 = 5 ×10 −6 , β = 9 ×10 −7 . By numerical simulations on the basis of MatCont package [9,10], we find that system (2.1) admits four patterns of equilibrium curves born from the infectionfree equilibrium and from the singularity of an infection equilibrium ( Fig.…”

Section: Bifurcations Inmentioning

confidence: 99%

“…All the other parameters in (1.2) have the same meaning as those in (1.1). Numerical simulations of model (1.2) in [2] found the case of asymptotic coexistence of immune system and virus, and found the case of virus eradication. The stability of infection-free equilibrium of (1.2) was examined in [48].…”

Section: Introductionmentioning

confidence: 95%

“…Indeed, biological studies indicate that CD4 + T cell activation plays a fundamental role in guiding CTL responses [11,26]. In papers [2,33,48], an HIV model is proposed that incorporates CTL responses to intracellular pathogens, CD4 + T cell proliferation due to stimulations of pathogens, and B cell responses to virus particles. The model admits only three state variables, which makes mathematical analysis tractable.…”

Section: Introductionmentioning

confidence: 99%

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Bifurcations of a mathematical model for HIV dynamics

Luo

Wang

Chen

et al. 2016

Journal of Mathematical Analysis and Applications

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This paper investigates bifurcations and stability of an HIV model that incorporates the immune responses. The conditions for the global stability of infection-free equilibrium and infection equilibrium are respectively established by the Lyapunov method and the geometric approach. The backward bifurcation from the infectionfree equilibrium is examined by analytical analysis. More interestingly, with the aid of mathematical analysis, we find a new type of bifurcations from an infection equilibrium, where a backward bifurcation curve emerges and can be continued to the place where the basic reproduction number is less than unity. By numerical simulations, we find a variety of dynamical behaviors of the model, which reveal the importance and complexity of immune responses in fighting HIV replication.

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Section: Backward Bifurcations From Ifementioning

confidence: 99%

Section: Bifurcations Inmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 95%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Bifurcations of a mathematical model for HIV dynamics

Luo

Wang

Chen

et al. 2016

Journal of Mathematical Analysis and Applications

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show abstract

“…This model allows to investigate time scale of quasi species evolution during superinfection (multiple infections at different times) or coinfection (simultaneous infection by different strains). For further details see [39].…”

Section: Application To Hiv Immunologymentioning

confidence: 99%

How the Mutational-Selection Interplay Organizes the Fitness Landscape

Bagnoli

Lió

2021

JNMP

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Fundamental questions posed in classical genetics since early 20th century are still fundamental in today post genomic age. What has changed is the availability of huge amount of molecular genetics information on a broad spectrum of species and a more powerful and rich methodological approach, particularly that one based on statistical mechanics and dynamical system theory which is providing unprecedented prediction power. Here we focus on the behavior of basic life forms such as bacteria and viruses which have small genomes and short generation times. We show that central issues of the evolutionary theory, i.e. how genotype, phenotype and fitness are related, the effect of positive and negative natural selection, the specie formation could be described by simple models which allow predictions and validation using experimental data.

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Modeling Evolutionary Dynamics of HIV Infection

Sguanci

Lió

Bagnoli

2006

Computational Methods in Systems Biology

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During the HIV infection several quasispecies of the virus arise, which are able to use different coreceptors, in particular the CCR5 and CXCR4 coreceptors (R5 and X4 phenotypes, respectively). The switch in coreceptor usage has been correlated with a faster progression of the disease to the AIDS phase. As several pharmaceutical companies are starting large phase III trials for R5 and X4 drugs, models are needed to predict the co-evolutionary and competitive dynamics of virus strains. We present a model of HIV early infection which describes the dynamics of R5 quasispecies and a model of HIV late infection which describes the R5 to X4 switch. We report the following findings: after superinfection or coinfection, quasispecies dynamics has time scales of several months and becomes even slower at low number of CD4+ T cells. The curve of CD4+ T cells decreases, during AIDS late stage, and can be described taking into account the X4 related Tumor Necrosis Factor dynamics. Phylogenetic inference of chemokine receptors suggests that viral mutational pathway may generate R5 variants able to interact with chemokine receptors different from CXCR4. This may explain the massive signaling disruptions in the immune system observed during AIDS late stages and may have relevance for vaccination and therapy.

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Modeling viral coevolution: HIV multi-clonal persistence and competition dynamics

Cited by 13 publications

References 46 publications

Bifurcations of a mathematical model for HIV dynamics

Bifurcations of a mathematical model for HIV dynamics

How the Mutational-Selection Interplay Organizes the Fitness Landscape

Modeling Evolutionary Dynamics of HIV Infection

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