Quasineutral multistability in an epidemiological-like model for defective-helper betacoronavirus infection in cell cultures

IF 4.4 2区工程技术 Q1 ENGINEERING, MULTIDISCIPLINARY

Applied Mathematical Modelling Pub Date : 2024-09-03 DOI:10.1016/j.apm.2024.115673

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引用次数: 0

Abstract

It is well known that, during replication, RNA viruses spontaneously generate defective viral genomes (DVGs). DVGs are unable to complete an infectious cycle autonomously and depend on coinfection with a wild-type helper virus (HV) for their replication and/or transmission. The study of the dynamics arising from a HV and its DVGs has been a longstanding question in virology. It has been shown that DVGs can modulate HV replication and, depending on the strength of interference, result in HV extinctions or self-sustained persistent fluctuations. Extensive experimental work has provided mechanistic explanations for DVG generation and compelling evidences of HV-DVGs virus coevolution. Some of these observations have been captured by mathematical models. Here, we develop and investigate an epidemiological-like mathematical model specifically designed to study the dynamics of betacoronavirus in cell culture experiments. The dynamics of the model is governed by several degenerate normally hyperbolic invariant manifolds given by quasineutral planes - i.e., filled by equilibrium points. Three different quasineutral planes have been identified depending on parameters and involving: (i) persistence of HV and DVGs; (ii) persistence of non-infected cells and DVG-infected cells; and (iii) persistence of DVG-infected cells and DVGs. Key parameters involved in these scenarios are the maximum burst size (B), the fraction of DVGs produced during HV replication (β), and the replication advantage of DVGs (δ). More precisely, in the case $0 < B < 1 + β$ the system displays tristability, where all three scenarios are present. In the case $1 + β 1 + β + δ$ , the scenario (i) becomes globally attractor. Scenarios (ii) and (iii) are compatible with the so-called self-curing since the HV is removed from the population. Sensitivity analyses indicate that model dynamics largely depend on DVGs production rate (β) and their replicative advantage (δ), and on both the infection rates and virus-induced cell deaths. Finally, the model has been fitted to single-passage experimental data using an artificial intelligence methodology based on genetic algorithms and key virological parameters have been estimated.

查看原文本刊更多论文

细胞培养物中缺陷辅助型 betacoronavirus 感染流行病学类模型中的准中性多态性

众所周知，RNA 病毒在复制过程中会自发产生缺陷病毒基因组（DVGs）。缺陷病毒基因组无法自主完成一个感染周期，其复制和/或传播依赖于与野生型辅助病毒（HV）的共同感染。研究 HV 及其 DVGs 的动态变化是病毒学的一个长期问题。研究表明，DVGs 可调节 HV 复制，并根据干扰强度导致 HV 灭绝或自我维持的持续波动。大量的实验工作为 DVG 的产生提供了机理解释，也为 HV-DVG 病毒的共同进化提供了有力证据。其中一些观察结果已被数学模型所捕捉。在此，我们开发并研究了一种类似于流行病学的数学模型，专门用于研究细胞培养实验中倍他克龙病毒的动态变化。该模型的动力学受几个退化的正双曲不变流形的支配，这些流形由准中性平面 - ，平衡点填充。根据参数的不同，确定了三种不同的准中性平面，涉及：（）HV 和 DVG 的持续存在；（）非感染细胞和 DVG 感染细胞的持续存在；以及（）DVG 感染细胞和 DVG 的持续存在。这些情况所涉及的关键参数包括：最大爆发大小（）、HV 复制过程中产生的 DVG 的比例（）以及 DVG 的复制优势（）。更确切地说，在系统显示三稳态的情况下，所有三种情况都会出现。在情况下，这种三稳态性持续存在，但吸引情景（）被简化为一个定义明确的半平面。对于，情景（）成为全局吸引子。方案（）和（）符合所谓的自我固化，因为 HV 已从群体中移除。敏感性分析表明，模型动态在很大程度上取决于 DVGs 的产生率（）及其复制优势（），以及感染率和病毒引起的细胞死亡。最后，利用基于遗传算法的人工智能方法将该模型与单程实验数据进行了拟合，并估算出了关键的病毒学参数。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Applied Mathematical Modelling 数学-工程：综合

CiteScore

9.80

自引率

8.00%

发文量

508

审稿时长

43 days

期刊介绍： Applied Mathematical Modelling focuses on research related to the mathematical modelling of engineering and environmental processes, manufacturing, and industrial systems. A significant emerging area of research activity involves multiphysics processes, and contributions in this area are particularly encouraged. This influential publication covers a wide spectrum of subjects including heat transfer, fluid mechanics, CFD, and transport phenomena; solid mechanics and mechanics of metals; electromagnets and MHD; reliability modelling and system optimization; finite volume, finite element, and boundary element procedures; modelling of inventory, industrial, manufacturing and logistics systems for viable decision making; civil engineering systems and structures; mineral and energy resources; relevant software engineering issues associated with CAD and CAE; and materials and metallurgical engineering. Applied Mathematical Modelling is primarily interested in papers developing increased insights into real-world problems through novel mathematical modelling, novel applications or a combination of these. Papers employing existing numerical techniques must demonstrate sufficient novelty in the solution of practical problems. Papers on fuzzy logic in decision-making or purely financial mathematics are normally not considered. Research on fractional differential equations, bifurcation, and numerical methods needs to include practical examples. Population dynamics must solve realistic scenarios. Papers in the area of logistics and business modelling should demonstrate meaningful managerial insight. Submissions with no real-world application will not be considered.