我国疾病动物模型的研究现状和展望

由于医学科学研究的需要,各类疾病动物模型被广泛用来研究人类疾病的发生发展机制、药物筛选以及治疗评价等.本文全面梳理了我国疾病动物模型的研究和发展现状,分析了我国在这方面的特色优势以及与国际上的差距,内容涵盖了肿瘤、神经及精神疾病、感染及免疫性疾病、心血管与代谢性疾病、药物筛选等不同领域.简要介绍了国家自然科学基金对疾病动物模型项目的资助情况,同时指出了我国疾病模型今后的主要发展方向.     

斑马鱼,人类疾病研究的理想模式动物

斑马鱼作为一种理想的模式动物已有广泛的应用,而其基因组测序工程的完成和斑马鱼的基因与人类基因高度的相似性,使得斑马鱼在人类疾病的研究中体现着重要的价值.本文从斑马鱼在几种人类重大疾病研究中的运用的角度综述了斑马鱼作为一种重要的模式动物对人类疾病研究的贡献.     

人类疾病的动物模型

发展对人类疾病有效的预测、预防、诊断和治疗等途径,一直是人口健康领域关注的焦点.任何人类疾病似乎都可归咎于遗传背景和环境因素的共同作用,并影响到疾病的发生、病程、药物疗效和预后等.最有效的研究策略足直接针对患者的各方面临床研究,但这一策略常常会而临着同一临床症状却有不同病因(异质性)、个体差异显著(如治疗效果因人而异)以及难以回溯性地研究人类疾病的发生、发展(如发病以前的事件或经历)等问题,而且医学伦理学的要求使得大量医学研究和新药新疗法不能直接应用于人体,必须先有动物实验阐明其安全性和必要性.最佳的研究策略足创建人类疾病的动物模型,因为可严格地控制病因、遗传背景、环境因子等,也可跟踪性研究动物模型病症的发生、发展、治疗反应和结局等,但这一策略也常常面临着一系列问题和误解.对此,在<动物学研究>出版<灵长类动物与人类疾病模型>专刊之际,撰写此评述性论文,将系列问题和误解一一提出,并讨论其应对策略.     

基因打靶技术在人类疾病动物模型研究中的应用

人类疾病动物模型在医学研究中起着非常重要的作用,而自然发生的人类疾病已远远不能满足医学研究的需要。利用基因打靶技术开展人类疾病动物模型的研究具有广阔的应用前景。本文就基因打靶技术及其在人类疾病动物模型研究中的应用做一介绍。     

基因编辑动物模型在人类疾病研究中的应用

近年来,随着以CRISPR/Cas9为代表的多种CRISPR系统的开发和不断改进,基因编辑技术逐渐完善,并广泛应用于人类疾病动物模型的制备。基因编辑动物模型为人类疾病的发病机理、病理过程以及预防和治疗等方面的研究提供了重要的素材。目前,用于人类疾病研究的基因编辑动物模型主要有小鼠、大鼠为代表的啮齿类动物模型和以猪为代表的大动物模型。其中啮齿类动物在机体各方面与人类差别较大,且寿命短,无法对人类疾病的研究和治疗提供有效评估和长期追踪;而猪在生理学、解剖学、营养学和遗传学等各方面与人类更接近,是器官移植和人类疾病研究领域重要的动物模型。文中主要介绍了基因编辑动物模型在神经退行性疾病、肥厚心肌病、癌症、免疫缺陷类疾病和代谢性疾病等5种人类疾病研究中的应用情况,以期为人类疾病研究及相关动物模型的制备提供参考。     

实验动物树鼩和人类疾病的树鼩模型研究概述

动物模型在生物医学领域(如回答人体各种重大生物学问题、解析人类疾病机理和新药研发等方面)已经做出了不可替代的巨大贡献。转化医学存在的问题使得树鼩(Tupaia belangeri chinensis)实验动物重新得到重视;人类疾病的树鼩模型也再次受到越来越多的关注。该文综述了国内外特别是近年来我国树鼩研究进展,包括树鼩基础生物学及动物模型方面取得的成绩,并分析了该领域目前存在的困难和问题,探讨了未来的一些研究方向。     

人类疾病动物模型是医药创新研究的前沿

人类疾病动物模型对医药研究起着支撑作用,是进行医药研究的必备工具之一.本文阐述了人类疾病动物模型在医药研究中所能发挥的作用,以及在医药研究的历史中所做出的贡献.最后,对疾病动物模型在医药创新研究中应用的前沿进行了展望.     

模型动物、动物模型与模式生物之辨析

模型动物、动物模型和模式生物的概念,形式上有相似之处,内涵却有所不同.在比较这3个概念的基础上,初步总结了动物模型的意义、分类和一些典型应用.     

模式动物斑马鱼在神经系统疾病研究中的应用

近年来,斑马鱼作为一种新型模式动物被广泛地应用于发育学、遗传学、行为学和分子生物学等研究领域。其具有繁殖能力强、发育迅速且同步、体外受精和幼体透明等生物学和形态学特点,经广泛培养和筛选突变品种,目前斑马鱼品系资源丰富。与其他非脊椎模式动物相比,它与人类有更高的同源性。本文主要介绍斑马鱼作为一种理想的模式动物,结合其特殊的行为学检测手段和分子生物学特点,在研究神经系统疾病的发病机制、构建疾病模型和相应药物筛选等方面的应用。     

综述与专论: 灵长类动物在人类神经系统疾病动物模型中的应用

灵长类动物遗传、行为、认知、生理、生化和解剖结构等生物学特性更接近人类,具有其他实验动物无法替代的高级脑功能结构及神经活动的优势,是研究人类神经系统疾病理想的模式动物,研究的结果更容易推广应用到人类。常被用来建立神经退行性疾病、精神性疾病等疾病的动物模型,研究其发病机制、病程的发生发展及治疗药物等,为人类神经科学及相关医学研究做出了不可替代的贡献。本文综述了近年来国内外灵长类动物在人类神经系统疾病动物模型研究中的应用进展,分析了该领域目前存在的困难和问题,探讨了未来的一些研究方向,以期为神系统经疾病的深入研究提供思路。     

Transgenic animals as models for human disease

Transgenic animals, especially mice, have been used quite extensively as models for various human diseases. At first, the level of scientific inquiry was driven by the need to establish the model. In many cases, these models may be considered quite crude because of their limitations. More recently, transgenic models of disease have become more refined and are currently being used to study the pathological mechanisms behind the disease rather than to just provide a model of the disease. Using some examples from the recent literature, we will document the current level and complexity of inquiry using transgenic animals. New techniques and techniques that may prove promising will be discussed. This revised version was published online in August 2006 with corrections to the Cover Date.     

Hepatic iron deposition in human disease and animal models

Iron deposition occurs in parenchymal cells of the liver in two major defects in human subjects (i) in primary iron overload (genetic haemochromatosis) and (ii) secondary to anaemias in which erythropolesis is increased (thalassaemia). Transfusional iron overload results in excessive storage primarily in cells of the reticule endothelial system. The storage patterns in these situations are quite characteristic. Excessive iron storage, particularly in parenchymal cells eventually results in fibrosis and cirrhosis. There is no animal model or iron overload which completely mimics genetics haemochromatosis but dietary iron loading with carbonyl iron or ferrocene does produce excessive parenchymal iron stores in the rat. Such models have been used to study iron toxicity and the action of iron chelators in the effective removal of excessive iron stores.     

Gene therapy for lysosomal storage diseases: the lessons and promise of animal models

There are more than 40 different forms of inherited lysosomal storage diseases (LSDs) known to occur in humans and the aggregate incidence has been estimated to approach 1 in 7000 live births. Most LSDs are associated with high morbidity and mortality and represent a significant burden on patients, their families, and health care providers. Except for symptomatic therapies, many LSDs remain untreatable, and gene therapy is among the only viable treatment options potentially available. Therapies for some LSDs do exist, or are under evaluation, including heterologous bone marrow transplantation (BMT), enzyme replacement therapy (ERT), and substrate reduction therapy (SRT), but these treatment options are associated with significant concerns, including high morbidity and mortality (BMT), limited positive outcomes (BMT), incomplete response to therapy (BMT, ERT, and SRT), life-long therapy (ERT, SRT), and cost (BMT, ERT, SRT). Gene therapy represents a potential alternative therapy, albeit a therapy with its own attendant concerns. Animal models of LSDs play a critical role in evaluating the efficacy and safety of therapy for many of these conditions. Naturally occurring animal homologs of LSDs have been described in the mouse, rat, dog, cat, guinea pig, emu, quail, goat, cattle, sheep, and pig. In this review we discuss those animal models that have been used in gene therapy experiments and those with promise for future evaluations.     

Linking animal models to human congenital diaphragmatic hernia

BACKGROUND: Congenital diaphragmatic hernia (CDH) is a major life-threatening malformation, occurring in approximately 1 in 3,000 live births. Over the years, different animal models have been used to gain insight into the etiology of this complex congenital anomaly and to develop treatment strategies. However, to date the pathogenic mechanism is still not understood, and treatment remains difficult because of the associated pulmonary hypoplasia and pulmonary hypertension. METHODS: In this review, data available from several animal models will be discussed. The retinoic acid signaling pathway (RA pathway, retinoid pathway) will be addressed as a developmental pathway that is potentially disrupted in the pathogenesis of CDH. Furthermore, genetic factors involved in diaphragm and lung development will be discussed. CONCLUSIONS: With this review article, we aim to provide a concise overview of the current most important experimental genetic data available in the field of CDH.     

Mito-mice: animal models for mitochondrial DNA-based diseases

We have successfully produced "Mito-mice" harbouring a pathogenic mtDNA mutation. We generated the mice by introducing mitochondria with a 4696 base-pair mtDNA deletion (Delta mtDNA4696) into mouse embryos. This deletion encompasses nucleotides 7759-12 454 and includes six tRNA genes and seven structural genes. In Mito-mice, the Delta mtDNA4696 is transmitted maternally, and induces mitochondrial dysfunction in various tissues. Most of the Mito-mice with high proportions of the Delta mtDNA4696 died at about age 6 months due to renal failure. Mito-mice are the first animal model for mtDNA-based diseases and will be valuable for studying pathogenesis and for identifying effective drug and gene therapies.     

Advantages and limitations of nonhuman primates as animal models in genetic research on complex diseases

Abstract: The genetic similarity between humans and nonhuman primates makes nonhuman primates uniquely suited as models for genetic research on complex physiological and behavioral phenotypes. By comparison with human subjects, nonhuman primates, like other animal models, have several advantages for these types of studies: 1) constant environmental conditions can be maintained over long periods of time, greatly increasing the power to detect genetic effects; 2) different environmental conditions can be imposed sequentially on individuals to characterize genotype-environment interactions; 3) complex pedigrees that are much more powerful for genetic analysis than typically available human pedigrees can be generated; 4) genetic hypotheses can be tested prospectively by selective matings; and 5) essential invasive and terminal experiments can be conducted. Limitations of genetic research with nonhuman primates include cost and availability. However, the ability to manipulate both genetic and environmental factors in captive primate populations indicates the promise of genetic research with these important animal models for illuminating complex disease processes. The utility of nonhuman primates for biomedical research on human health problems is illustrated by examples concerning the use of baboons in studies of osteoporosis, alcohol metabolism, and lipoproteins.