Abstract
Replication of Human Immunodeficiency Virus type 1 (HIV) in infected CD4+ T cells represents a key driver of HIV infection. The HIV life cycle is characterised by the heterogeneity of infected cells with respect to multiplicity of infection and the variability in viral progeny. This heterogeneity can result from the phenotypic diversity of infected cells as well as from random effects and fluctuations in the kinetics of biochemical reactions underlying the virus replication cycle. To quantify the contribution of stochastic effects to the variability of HIV life cycle kinetics, we propose a high-resolution mathematical model formulated as a Markov chain jump process. The model is applied to generate the statistical characteristics of the (i) cell infection multiplicity, (ii) cooperative nature of viral replication, and (iii) variability in virus secretion by phenotypically identical cells. We show that the infection with a fixed number of viruses per CD4+ T cell leads to some heterogeneity of infected cells with respect to the number of integrated proviral genomes. The bottleneck factors in the virus production are identified, including the Gag-Pol proteins. Sensitivity analysis enables ranking of the model parameters with respect to the strength of their impact on the size of viral progeny. The first three globally influential parameters are the transport of genomic mRNA to membrane, the tolerance of transcription activation to Tat-mediated regulation, and the degradation of free and mature virions. These can be considered as potential therapeutical targets.
Highlights
Infection with the Human Immunodeficiency Virus type-1 (HIV) remains a global problem of public health concern, with more than 70 million people infected since the early 1980s [1]
We have recently developed a detailed in silico model of the Human Immunodeficiency Virus type 1 (HIV) life cycle in productively infected CD4 T cells [15] formulated with a system of 24 ordinary differential equations (ODE)
The HIV-1 replication cycle presented in Figure 1 consists of multiple stages described below
Summary
Infection with the Human Immunodeficiency Virus type-1 (HIV) remains a global problem of public health concern, with more than 70 million people infected since the early 1980s [1]. We have recently developed a detailed in silico model of the HIV life cycle in productively infected CD4 T cells [15] formulated with a system of 24 ordinary differential equations (ODE). This deterministic model enables estimation of biochemical parameters of HIV replication. We formulate the stochastic Markov chain-type model of HIV replication in productively infected cells in the form of Gillespie’s algorithm [17]. Cell-to-cell variability in HIV progeny production; Multiplicity of single-cell infection; Global sensitivity of specific reaction steps on net virus production. Our study delineates the contribution of random effects to (i) the multiplicity of infection, (ii) the cooperative nature of viral replication, and (iii) the variability in the scale of virus secretion by phenotypically identical cells
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