Stochastic Model of Acidification, Activation of Hemagglutinin and Escape of Influenza Viruses from an Endosome

Lagache, Thibault; Sieben, Christian; Meyer, Tim; Herrmann, Andreas; Holcman, David

doi:10.3389/fphy.2017.00025

Cited by 18 publications

(21 citation statements)

References 42 publications

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“…Specifically, protons weaken the interactions between HA-M1, M1-M1, and M1-vRNP, while the K + ions promote the solubilisation of vRNP complexes. Within LEs, where the microenvironmental pH reaches less than 5.5, irreversible changes take place within the viral core, which are needed for the efficient dissociation of the viral shell from vRNP complexes [81,92].…”

Section: Influenza Virus Priming In Endosomesmentioning

confidence: 99%

Microtubules in Influenza Virus Entry and Egress

Simpson

Yamauchi

2020

Viruses

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Influenza viruses are respiratory pathogens that represent a significant threat to public health, despite the large-scale implementation of vaccination programs. It is necessary to understand the detailed and complex interactions between influenza virus and its host cells in order to identify successful strategies for therapeutic intervention. During viral entry, the cellular microenvironment presents invading pathogens with a series of obstacles that must be overcome to infect permissive cells. Influenza hijacks numerous host cell proteins and associated biological pathways during its journey into the cell, responding to environmental cues in order to successfully replicate. The cellular cytoskeleton and its constituent microtubules represent a heavily exploited network during viral infection. Cytoskeletal filaments provide a dynamic scaffold for subcellular viral trafficking, as well as virus-host interactions with cellular machineries that are essential for efficient uncoating, replication, and egress. In addition, influenza virus infection results in structural changes in the microtubule network, which itself has consequences for viral replication. Microtubules, their functional roles in normal cell biology, and their exploitation by influenza viruses will be the focus of this review.

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Section: Influenza Virus Priming In Endosomesmentioning

confidence: 99%

Microtubules in Influenza Virus Entry and Egress

Simpson

Yamauchi

2020

Viruses

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“…Also, the authors of Ref. [14] consider the acidification of individual endosomes, without considering interactions between them. Finally, it is worth mentioning that, in Ref.…”

Section: Mathematical Framework Of Endosome Dynamics and Maturationmentioning

confidence: 99%

“…Our approach here takes a different route beyond deterministic descriptions of endosomal dynamics at the cellular level [19,26,28,29], or at the single endosome level [14,15,23]. As we have discussed earlier, the former presumes that Rab dynamics at the cellular scale can be studied from the observation of endosomal averages, and, the latter, focuses on biochemical reactions on the endosome membrane, which do not include the interaction between endosomes.…”

Section: Mathematical Framework Of Endosome Dynamics and Maturationmentioning

confidence: 99%

“…Besides their role as experimental markers, different Rab molecules have been identified as central regulators of the endosomal transport pathway [13]. Of particular relevance, is the fact that endosomal pH has been experimentally linked to different levels of Rab5 and Rab7 [5,[13][14][15]. Given the large variability observed in viral escape times [9,11,16], it is timely to ask ourselves the following questions: (i) is pH alone the main trigger of viral escape, (ii) is the pH dependence gradual (analogical) or abrupt (digital), and (iii) can endosome maturation and dynamics explain the observed heterogeneity in the distribution of viral escape times.…”

Section: Introductionmentioning

confidence: 99%

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Fusion and fission events regulate endosome maturation and viral escape

Castro

Lythe

Smit

et al. 2020

Preprint

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Many intra-cellular processes rely on transport by endosomes. Recent experimental techniques have provided insights into organelle maturation and its specific role in, for instance, the ability of a virus to escape an endosome and release its genetic material in the cytoplasm. Endosome maturation and dynamics depend on GTPases called Rabs, found on their membrane. Here, we introduce a mathematical framework, combining coagulation and fragmentation of endosomes with two variables internal to each organelle, to model endosomes as intra-cellular compartments characterised by their levels of (active) Rab5 and Rab7. The key element in our framework is the ``per-cell endosomal distribution'' and its its dynamical equation or Boltzmann equation. The Boltzmann equation, then, allows one to deduce simple equations for the total number of endosomes in a cell, and for the mean and standard deviation of the Rab5 and Rab7 levels. We compare our solutions with experimental data sets of Dengue viral escape from endosomes. The relationship between endosomal Rab levels and pH suggests a mechanism which can account for the observed variability in viral escape times, which in turn regulate the viability of a viral intra-cellular infection.

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“…Moreover, a computational framework is proposed that focuses on kinetic model selection for HIV viral entry through binding to receptor and coreceptor expression based on their predictions to infectivity measurement (Mistry, D'Orsogna, Webb, Lee, & Chou, 2016). Similarly, in other biological systems, the Monte‐Carlo simulations have been performed to study endosomal fusion and escape of influenza (Lagache, Sieben, Meyer, Herrmann, & Holcman, 2017) and gene expression profiles in normal and cancer cells (Ogundijo & Wang, 2017; Zhang et al, 1997). The probability distribution for protein expression and the number of packaged virus in this study corresponds biologically to the variability in the expression and packaging process, with some cells getting infected and undergoing viral protein expression without mutations, while other cells in the suspension culture undergo mutations due to the transposon insertion (Giri et al, 2010).…”

Section: Introductionmentioning

confidence: 99%

Statistical modeling of cell‐to‐cell variability in viral infection during passaging in suspension cell culture: Application in Monte‐Carlo simulation

Saxena

Suryateja

Upadhyay

et al. 2020

Biotech & Bioengineering

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Packaging during the passaging of viruses in cell cultures yields various phenotypes and is regulated by viral protein expression in infected cells. Although such a packaging mechanism has a profound effect in controlling the virus yield, little is known about the underlying statistical models followed by virus packaging and protein expression among cells infected with the virus. A predictive framework combining identification of the probability density function (PDF) based on log‐likelihood and using the PDF for Monte‐Carlo simulations is developed. The Birnbaum–Saunders distribution was found to be consistent with all three‐virus packaging levels, including nucleocapsids/occlusion‐derived virus (ODV), ODVs/polyhedra, and polyhedra/cell for both wild‐type and genetically modified AcMNPV. Next, it was demonstrated that PDF fitting could be used to compare two viruses having distinctly different genetic configurations. Finally, the identified PDF can be incorporated in RNA synthesis parameters for baculovirus infection to predict the cell‐to‐cell variability in protein expression using Monte‐Carlo simulations. The proposed tool can be used for the estimation of uncertainty in the kinetic parameter and prediction of cell‐to‐cell variability for other biological systems.

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Stochastic Model of Acidification, Activation of Hemagglutinin and Escape of Influenza Viruses from an Endosome

Cited by 18 publications

References 42 publications

Microtubules in Influenza Virus Entry and Egress

Microtubules in Influenza Virus Entry and Egress

Fusion and fission events regulate endosome maturation and viral escape

Statistical modeling of cell‐to‐cell variability in viral infection during passaging in suspension cell culture: Application in Monte‐Carlo simulation

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