利用有效传播数对宿主内疟疾动态的调控机制进行划分。
Partitioning regulatory mechanisms of within-host malaria dynamics using the effective propagation number.
机构信息
Department of Zoology, Oxford University, Oxford OX1 3PS, UK.
出版信息
Science. 2011 Aug 19;333(6045):984-8. doi: 10.1126/science.1204588.
Abstract
Immune clearance and resource limitation (via red blood cell depletion) shape the peaks and troughs of malaria parasitemia, which in turn affect disease severity and transmission. Quantitatively partitioning the relative roles of these effects through time is challenging. Using data from rodent malaria, we estimated the effective propagation number, which reflects the relative importance of contrasting within-host control mechanisms through time and is sensitive to the inoculating parasite dose. Our analysis showed that the capacity of innate responses to restrict initial parasite growth saturates with parasite dose and that experimentally enhanced innate immunity can affect parasite density indirectly via resource depletion. Such a statistical approach offers a tool to improve targeting of drugs or vaccines for human therapy by revealing the dynamics and interactions of within-host regulatory mechanisms.
摘要
免疫清除和资源限制(通过红细胞耗竭)塑造了疟疾寄生虫血症的高峰和低谷,进而影响疾病的严重程度和传播。定量划分这些效应在时间上的相对作用具有挑战性。利用来自啮齿动物疟疾的数据,我们估计了有效繁殖数,该数反映了不同的宿主内控制机制随时间的相对重要性,并且对接种的寄生虫剂量敏感。我们的分析表明,先天反应限制初始寄生虫生长的能力随寄生虫剂量而饱和,并且实验增强的先天免疫可以通过资源耗竭间接影响寄生虫密度。这种统计方法通过揭示宿主内调节机制的动态和相互作用,为改善人类治疗药物或疫苗的靶向提供了一种工具。
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