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.     

模型动物斑马鱼及其特定病原净化

虽然斑马鱼等实验用鱼已经成为生命科学研究的一类重要模型动物,但对于在集约化人工养殖过程中实验鱼的疾病却研究很少。实验用斑马鱼严重的健康问题使其在研究中常出现大面积甚至毁灭性的死亡。常见的感染也可以危及很多实验室的鱼群。因此,培育健康的实验用鱼群,建立必要的质量控制标准已经势在必行。本文收集和分析了大量相关的资料,为我国实验用鱼疾病的控制以及标准化研究和培育SPF斑马鱼提供帮助。     

二氢叶酸还原酶基因在斑马鱼神经系统发育过程中的作用

目的观察二氢叶酸还原酶基因(DHFR)功能阻抑斑马鱼胚胎的颅脑部发育情况,初步探讨二氢叶酸还原酶基因在斑马鱼神经系统发育过程中的作用。方法采用显微注射吗啡啉修饰的反义核苷酸(MO)的方法进行DHFR表达阻抑。胚胎发育至受精后48hpf观察胚胎的颅部发育情况,在60hpf时经石蜡切片进一步观察胚胎的脑发育状况。利用胚胎整体原位杂交的方法检测影响神经系统发育的关键因子ngn1和huc的表达情况。结果显微注射MO可成功的进行DHFR表达阻抑。DHFR表达阻抑组胚胎存在颅脑部发育明显异常和ngn1、huc的表达强度明显减弱,且与显微注射的MO剂量呈正相关。结论DHFR在斑马鱼颅脑发育中有重要作用;其功能阻抑可导致胚胎颅脑部发育异常,其机理与ngn1和huc的的表达减弱有关。     

斑马鱼在新药发现中的应用

在过去20年里,斑马鱼已成为一种重要的模式脊椎动物,在发育、遗传、免疫、肿瘤和毒理等诸多研究领域中被广泛应用。近年来,斑马鱼作为活体模型越来越多地应用于某些生物学过程的药物筛选。通过斑马鱼初步筛选,在药物研发初期可确定化合物的生物学活性、毒性以及副作用等。最近的研究还发现,斑马鱼不仅用于新药筛选,还可用于药物结构的优化。本文重点介绍斑马鱼在新药发现中的应用。     

斑马鱼模型在药物筛选中的应用

斑马鱼具有子代数量多、体外受精、胚胎透明、可以做大规模遗传突变筛选等生物学特性, 因此成为一种良好的脊椎动物模式生物。随着研究的深入, 斑马鱼不仅应用于遗传学和发育生物学研究, 而且拓展和延伸到疾病模型和药物筛选领域。作为一种整体动物模型, 斑马鱼能够全面地检测评估化合物的活性和副作用, 实现高内涵筛选。近年来, 科学家们不断地发展出新的斑马鱼疾病模型和新的筛选技术, 并找到了一批活性化合物。这些化合物大多数在哺乳动物模型中也有相似的效果, 其中前列腺素E2(dmPGE2)和来氟米特(Leflunomide)已经进入临床实验, 分别用来促进脐带血细胞移植后的增殖和治疗黑素瘤。这些成果显示了斑马鱼模型很适合用于药物筛选。文章概括介绍了斑马鱼模型的特点和近年来在疾病模型和药物筛选方面的进展, 希望能够帮助人们了解斑马鱼在新药研发中的应用, 并开展基于斑马鱼模型的药物筛选。     

斑马鱼:在生命科学中畅游

模式动物是生命科学研究的重要材料,为生命科学的发展做出了重要的贡献。自20世纪90年代初以来,斑马鱼因其多方面的优点已成为模式动物家族中重要的一员,受到越来越多的重视和利用。目前,斑马鱼被广泛地用于发育生物学、遗传学、肿瘤学、药物学、毒理与环保等方面的研究,不断涌现新的研究成果。     

SELEX技术在神经系统疾病研究中的应用

配体指数级富集系统进化（systematic evolution of ligands by exponential enrichment,SELEX）技术是一种组合化学技术,可经过反复筛选扩增得到针对靶分子的高亲和力和高特异性的适配子.适配子通过识别、结合特定靶分子并对其进行功能调控从而达到对疾病诊断和治疗的目的 .近年来SELEX技术在神经系统功能和疾病研究中的应用越来越多.现已经筛选出针对朊蛋白、肌腱蛋白-C、β-淀粉样肽、乙酰胆碱受体的自身抗体等靶标的适配子,促进了对朊病毒病、脑肿瘤、阿茨海默病、重症肌无力等神经系统疾病的诊断和治疗研究,为这些疾病的诊治提供了新的研究工具.     

斑马鱼与人类疾病模型的研究

斑马鱼是一种很好的用于研究脊椎动物胚胎学和发育遗传学的模型生物,它有其他模型生物所不具备的优点。最近研究较多的是在斑马鱼中建立人类疾病研究模型。本文就斑马鱼在造血障碍和心血管障碍等方面的疾病模型建立及主要的技术做简要论述。     

磁生物学在模式动物斑马鱼中的研究进展

磁场在生活中无处不在,为探究磁场的生物学效应,大量研究工作已经开展。斑马鱼作为新兴的模式生物,在探明磁场与生理功能关系方面具有重要作用。本文梳理了当前磁生物学在斑马鱼上的相关研究。已有研究表明磁场会导致斑马鱼生长畸形、发育延迟和细胞凋亡,影响斑马鱼的游泳行为和方向偏好,也会改变其昼夜节律,还会对生殖和免疫功能产生影响;斑马鱼可能具有不止一种的磁感应机制,除了目前已提出的磁矿石晶体模型、自由基对模型和电磁感应模型等磁感应模型外,磁场引起的DNA损伤、Ca²⁺稳态异常、微管聚合速率改变、应激反应、生物钟基因cry的表达改变等可部分解释上述现象。针对存在的生物磁感应研究中存在的参数不一和机制不清晰等问题,结合斑马鱼优势,本文提出未来斑马鱼在磁生物学研究中的潜在方向：基于斑马鱼建立磁场和生物参数可控的磁生物学研究模型;非侵入性活体追踪相关生命活动过程,可视化研究磁生物学现象;基于Cry蛋白开展磁场与生物节律关系的研究。     

斑马鱼在生命科学研究中的应用

利用模式生物进行研究是推动生命科学发展的主要手段之一.斑马鱼已成为继小鼠之后的又一个重要的模式脊椎动物.本文将重点介绍斑马鱼在学习记忆和疾病研究领域中的应用,以及我国推动斑马鱼相关研究的策略.     

Zebrafish as a new animal model for movement disorders

The zebrafish, long recognized as a model organism for the analysis of basic developmental processes, is now also emerging as an alternative animal model for human diseases. This review will first provide an overview of the particular characteristics of zebrafish in general and their dopaminergic nervous system in particular. We will then summarize all work undertaken so far to establish zebrafish as a new animal model for movement disorders and will finally emphasize its particular strength – amenability to high throughput in vivo drug screening.     

Thioacetamide induced liver damage in zebrafish embryo as a disease model for steatohepatitis

Summary Steatohepatitis has recently been increasing as a cofactor influencing the progression of fibrosis, cirrhosis, adenoma and carcinoma in liver; however, the mechanisms by which it contributes to liver injury remain uncertain. We induced steatohepatitis in zebrafish embryos using thioacetamide (TAA). TUNEL assay revealed significant increasing of apoptosis in liver after 5 days post fertilization and the increasing of apoptosis was observed to be associated with the up-regulation of apoptotic genes such as, bad, bax, P-38a, caspase-3 and 8, and JNK-1. Histological sections by oil red O stain showed the accumulation of fatty droplets which causes the pushing of the nucleus towards one side. Up-regulation of steatosis markers such as, ACC, adiponectin, PTL, CEBP- and , SREBP-1 was also observed. Furthermore, the elevation of glutathione peroxidase in TAA treated embryos indicated that TAA induces lipid peroxidation which leads to causes liver damage. Zebrafish has already been considered as a good human disease model and in this context; TAA-treated zebrafish may serve as a good animal model to study the molecular pathogenesis of steatohepatitis. Moreover, non-availability of specific drugs to prevent steatohepatitis, this animal model may serve as a powerful preclinical platform to study the therapeutic strategies and for evaluating chemoprevention strategies for this disease.     

雌激素受体与神经系统疾病

雌激素受体是类固醇激素受体超家族成员之一,是一种配体依赖性转录因子,具有广泛的生物学功能。雌激素受体在脑内具有广泛的分布,且与一些神经系统疾病的发生发展相关。就雌激素受体在脑内的分布及其与神经系统疾病的关系进行论述。     

Bioelectrical activity of the central nervous system among populations in a rare earth element area

Auditory brainstem electric response (ABR) and somatosensory evoked potential (SEP) of 21 subjects (41 ears) among villagers in a rare earth element (REE) area in Gan County, Jiangxi, China, were studied. No difference in ABR between the subjects from the REE area and the control group was noted. However, the conduction detected by SEP from the median nerve to the thalamus (P ₁₅) was shortened (P<0.05), especially to the first-grade primary somatosensory responsive region (S ₁) (P<0.01) and the amplitude of S₁ decreased (P<0.05), indicating that REE was difficult to accumulate in the brainstem, but it was susceptible to cerebral cortex, thus causing subclinical damage. This condition was confirmed in the animal experiment. It was suggested that the toxicity through long-term intake of small doses of REE might not be negligible, and the hazard of REE environments should be investigated.     

糖基转移酶在神经系统中的作用

神经系统的发育及其正常功能的维持受到精确的控制,其调控异常导致的神经系统疾病成为危害健康的重要因素。研究神经系统的发育及其疾病发生的分子机制是生命科学的热点。糖基转移酶是一组催化糖链合成及糖链与蛋白质或者脂质形成复合物的酶类。糖基转移酶可以调节神经细胞表面多种蛋白质及脂质的糖基化,参与神经系统的发生及多种疾病发病过程的调控。对糖基转移酶在神经系统发育和疾病中的作用做一综述。     

p53-dependent neuronal cell death in a DJ-1-deficient zebrafish model of Parkinson's disease

Mutations in DJ-1 lead to early onset Parkinson's disease (PD). The aim of this study was to elucidate further the underlying mechanisms leading to neuronal cell death in DJ-1 deficiency in vivo and determine whether the observed cell loss could be prevented pharmacologically. Inactivation of DJ-1 in zebrafish, Danio rerio, resulted in loss of dopaminergic neurons after exposure to hydrogen peroxide and the proteasome inhibitor MG132. DJ-1 knockdown by itself already resulted in increased p53 and Bax expression levels prior to toxin exposure without marked neuronal cell death, suggesting subthreshold activation of cell death pathways in DJ-1 deficiency. Proteasome inhibition led to a further increase of p53 and Bax expression with widespread neuronal cell death. Pharmacological p53 inhibition either before or during MG132 exposure in vivo prevented dopaminergic neuronal cell death in both cases. Simultaneous knockdown of DJ-1 and the negative p53 regulator mdm2 led to dopaminergic neuronal cell death even without toxin exposure, further implicating involvement of p53 in DJ-1 deficiency-mediated neuronal cell loss. Our study demonstrates the utility of zebrafish as a new animal model to study PD gene defects and suggests that modulation of downstream mechanisms, such as p53 inhibition, may be of therapeutic benefit.     

钙网蛋白与神经系统病变

钙网蛋白（calreticulin,CRT）是内质网中的一种多功能的分子伴侣,在协助蛋白质正确折叠和维持细胞Ca2＋稳态（Ca2＋信号）中发挥重要作用。近来的研究发现,钙网蛋白与神经系统病变包括阿尔茨海默氏病、帕金森病等有密切关系。     

Transgenic zebrafish expressing fluorescent proteins in central nervous system neurons

Zebrafish is a powerful model system for investigations of vertebrate neural development. The animal has also become an important model for studies of neuronal function. Both in developmental and functional studies, transgenic zebrafish expressing fluorescent proteins in central nervous system neurons have been playing important roles. We review here the methods for producing transgenic zebrafish. Recent advances in transposon- or bacterial artificial chromosome-based transgenesis greatly facilitate the creation of useful lines. We also present our study on alx -positive neurons to reveal how transgenic zebrafish expressing fluorescent proteins in a specific class of neurons can be used to investigate their development and function.