Geifman Nophar, Rubin Eitan
Department of Microbiology, Immunology and Genetics, Faculty of Medical Sciences and The National Institute of Biotechnology in the Negev, Ben Gurion University, Beer-Sheva, Israel.
PLoS One. 2013 Dec 3;8(12):e81114. doi: 10.1371/journal.pone.0081114. eCollection 2013.
Similarities between mice and humans lead to generation of many mouse models of human disease. However, differences between the species often result in mice being unreliable as preclinical models for human disease. One difference that might play a role in lowering the predictivity of mice models to human diseases is age. Despite the important role age plays in medicine, it is too often considered only casually when considering mouse models.
We developed the mouse-Age Phenotype Knowledgebase, which holds knowledge about age-related phenotypic patterns in mice. The knowledgebase was extensively populated with literature-derived data using text mining techniques. We then mapped between ages in humans and mice by comparing the age distribution pattern for 887 diseases in both species.
The knowledgebase was populated with over 9800 instances generated by a text-mining pipeline. The quality of the data was manually evaluated, and was found to be of high accuracy (estimated precision >86%). Furthermore, grouping together diseases that share similar age patterns in mice resulted in clusters that mirror actual biomedical knowledge. Using these data, we matched age distribution patterns in mice and in humans, allowing for age differences by shifting either of the patterns. High correlation (r(2)>0.5) was found for 223 diseases. The results clearly indicate a difference in the age mapping between different diseases: age 30 years in human is mapped to 120 days in mice for Leukemia, but to 295 days for Anemia. Based on these results we generated a mice-to-human age map which is publicly available.
We present here the development of the mouse-APK, its population with literature-derived data and its use to map ages in mice and human for 223 diseases. These results present a further step made to bridging the gap between humans and mice in biomedical research.
小鼠与人类之间的相似性促使产生了许多人类疾病的小鼠模型。然而,物种间的差异常常导致小鼠作为人类疾病临床前模型并不可靠。年龄可能是导致小鼠模型对人类疾病预测性降低的一个因素。尽管年龄在医学中起着重要作用,但在考虑小鼠模型时却常常被忽视。
我们开发了小鼠年龄表型知识库,其中包含有关小鼠年龄相关表型模式的知识。该知识库使用文本挖掘技术广泛填充了来自文献的数据。然后,通过比较两个物种中887种疾病的年龄分布模式,我们绘制了人类和小鼠年龄之间的对应关系。
该知识库包含通过文本挖掘管道生成的9800多个实例。数据质量经过人工评估,发现具有很高的准确性(估计精度>86%)。此外,将小鼠中具有相似年龄模式的疾病归为一组,得到的聚类反映了实际的生物医学知识。利用这些数据,我们匹配了小鼠和人类的年龄分布模式,通过移动其中一种模式来考虑年龄差异。发现223种疾病具有高度相关性(r(2)>0.5)。结果清楚地表明不同疾病的年龄映射存在差异:白血病中人类30岁对应小鼠120天,但贫血则对应295天。基于这些结果,我们生成了一个公开可用的小鼠到人类年龄映射图。
我们在此展示了小鼠年龄表型知识库的开发、用文献数据填充该知识库以及用于绘制223种疾病小鼠和人类年龄映射的过程。这些结果朝着弥合生物医学研究中人类和小鼠之间的差距又迈进了一步。
