Illuminating HBV with multi-scale modeling

S. Means, M. A. Ali, H. Ho
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Abstract

Unfortunately for the estimated 250 million sufferers of chronic hepatitis-B viral (HBV) infection worldwide, the liver terrain is typically ignored. An immuno-tolerant environment attractive for pathogens, the essential metabolic roles and structural features of the liver are aligned with distinctive gradients of oxygen and nutrients established along blood flows through fundamental hepatic processing units known as sinusoids. Capillaries surrounded by banks of hepatocytes, sinusoids express spatial configurations and concentrations of not only metabolic roles but also immune cell localisations, blood filtering and transporter specialisations: the liver terrain. HBV targets proteins regulating gluconeogenesis, a crucial liver function of blood glucose management, highly active at blood entry points—the periportal sites of sinusoids. Meanwhile, at these same sites, specialised liver macrophages, Kupffer cells (KC), aggregate and perform critical pathogen capture, detection and signaling for modulating immune responses. In tandem with KC, liver sinusoidal endothelial cells (LSECs) complement KC blood filtration and capture of pathogens as well as determine KC aggregation at the periportal sites. Failure of these systems to establish critical spatial configurations could ironically facilitate HBV invasion and entrenchment. Investigating the impacts of spatial and structural variations on the HBV infection dynamic is experimentally challenging at best. Alternatively, mathematical modeling methods provide exquisite control over said variations, permitting teasing out the subtle and competing dynamics at play within the liver terrain. Coordinating with experimental observations, multi-scale modeling methods hold promise to illuminate HBV reliance on features of the liver terrain, and potentially how it may be defeated.
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用多尺度建模照亮HBV
不幸的是,对于全球约2.5亿慢性乙型肝炎病毒(HBV)感染患者来说,肝脏地形通常被忽视。作为一个对病原体有吸引力的免疫耐受环境,肝脏的基本代谢作用和结构特征与沿着血液流经称为血窦的基本肝脏处理单元建立的独特的氧气和营养梯度相一致。毛细血管被肝细胞库包围,血窦不仅表达代谢作用的空间配置和浓度,还表达免疫细胞定位、血液过滤和转运蛋白专门化:肝脏地形。HBV靶向调节糖异生的蛋白质,糖异生是血糖管理的关键肝功能,在血液入口点(血窦的门周部位)高度活跃。同时,在这些相同的位点,专门的肝巨噬细胞库普弗细胞(KC)聚集并执行关键的病原体捕获、检测和信号传导,以调节免疫反应。肝窦内皮细胞(LSEC)与KC协同作用,补充KC的血液过滤和病原体捕获,并确定KC在门周部位的聚集。具有讽刺意味的是,这些系统未能建立关键的空间配置可能会促进HBV的侵袭和巩固。研究空间和结构变化对HBV感染动态的影响充其量是实验上的挑战。或者,数学建模方法对所述变化提供了精细的控制,从而可以梳理出肝脏地形内微妙而竞争的动态。与实验观察相协调,多尺度建模方法有望阐明HBV对肝脏地形特征的依赖,以及如何战胜它。
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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