秀丽隐杆线虫体内脂肪染色方法的探究

近几十年来,秀丽隐杆线虫(Caenorhabditis elegans)因其结构简单、通体透明、生命周期短和易于培养,常作为一种模式生物被广泛用于现代发育生物学、遗传学、抗衰老和及脂肪调控等方面的研究。本文探索了一种对秀丽隐杆线虫体内脂肪的油红O染色方法,利用1%Triton X-100的透过作用,线虫体内脂滴可被油红O更好的着色,镜下观察颜色鲜红,染色效果较好,为以后研究线虫脂肪调控奠定了基础。     

秀丽隐杆线虫体内脂滴的尼罗红染色观察

秀丽隐杆线虫(Caenorhabditis elegans)为常见的生物实验模式之一,也是最近作为研究脂肪沉积的一种较理想的模型,其肠道是脂肪沉积的主要场所。本文使用尼罗红染液对秀丽隐杆线虫体内的脂肪进行染色,在荧光显微镜下可见其肠道周围呈现强烈桔黄色,较好的显示了线虫体内的脂肪沉积部位,为后续研究线虫脂肪沉积的调控机制奠定了基础。     

秀丽隐杆线虫脂肪沉积研究进展

脂肪的过度沉积会引发多种疾病,如心脏病、高血压、高甘油三酯血症、Ⅱ型糖尿病等。小白鼠(Mus musculus)和猪(Sus domesticus)是常用的研究脂肪沉积的模式动物,近年来随着研究的深入,发现脂肪代谢调控网络错综复杂,调控因子相互作用。秀丽隐杆线虫(Caenorhabditis elegans)具有结构简单、身体透明、便于观察、繁殖周期短、易于人工培养等特征,因此使得秀丽隐杆线虫进行脂肪调控的研究成为了可能。本文通过总结国内外线虫脂肪沉积方面的研究,综述秀丽隐杆线虫研究脂肪沉积的进展。     

不同浓度亳菊水提物对秀丽隐杆线虫脂滴凝聚影响观察

目的探讨毫菊对秀丽隐杆线虫脂肪沉积的影响。方法用不同浓度毫菊水提取液配制NGM培养基,培养同步化秀丽隐杆线虫,成虫经油红0染色,异丙醇萃取,测定OD值,并与普通NGM培养基培养的同步化线虫相比较。结果随着浓度的提高,线虫体内的脂肪沉积量呈现出一定的曲线变化,其具体机制有待于进一步研究。     

必需氨基酸延缓秀丽隐杆线虫衰老的研究

利用模式生物秀丽隐杆线虫,考察8种人体必需氨基酸对衰老的影响。首先建立秀丽隐杆线虫寿命模型,以雷帕霉素为阳性对照药,分别考察8种必需氨基酸对线虫生存时间的影响。再用筛选出的氨基酸处理线虫21d,通过秀丽隐杆线虫-绿脓杆菌感染模型,考察氨基酸对线虫的抗感染能力的影响,利用实时荧光定量Real-Time RT-PCR方法检测氨基酸处理线虫后DAF-16/FOXO下游基因和免疫相关基因的表达水平。结果表明8种必需氨基酸中苏氨酸和异亮氨酸既能延长野生型线虫的寿命又能延长daf-16突变型线虫的寿命,同时还能增强秀丽隐杆线虫抗绿脓杆菌感染的能力,并提高免疫相关基因lys-7、clec-67的表达水平,而DAF-16/FOXO下游基因表达没有明显变化。因此苏氨酸和异亮氨酸能延长线虫寿命、提高抗感染能力,且对线虫寿命的延长作用不完全依赖于DAF-16/FOXO转录因子。     

秀丽隐杆线虫先天免疫信号转导途径

秀丽隐杆线虫因其结构简单、易于培养、生命周期短等特点作为一种模式生物已广泛应用于神经系统、衰老机制及细胞程序性死亡的研究。与高等生物不同,秀丽隐杆线虫缺少适应性免疫途径,只有先天免疫途径在抗病原菌、抗氧化应激等方面发挥重要的作用。其体内的胰岛素/胰岛素样生长因子(insulin/ IGF-1)、转化生长因子β(transforming growth factor β,TGF-β)、丝裂原激活的蛋白激酶(mitogen activated protein kinases,MAPK)和细胞程序性死亡(programmed cell death,PCD)4条免疫相关信号转导途径在不同的环境发挥着主要作用。同时,秀丽隐杆线虫的先天免疫系统在进化中有许多保守之处,这为高等生物的免疫机制研究提供了新思路。据此,就有关秀丽隐杆线虫先天免疫信号转导途径的研究进展进行了简述,期望能为人类等高等生物相关联的免疫作用研究提供借鉴和参考。     

秀丽隐杆线虫在高校遗传学实验中的应用

秀丽隐杆线虫(Caenorhabditiselegans)是模式生物中的重要成员之一,因其实验成本低,实验周期短,非常适宜用于高校的遗传学实验教学中。线虫在实验教学中的使用,一方面可以有效地丰富高校实验教学的内容,另一方面也可以很好地激发学生的学习兴趣。本文介绍了线虫在遗传学实验教学中的应用实例,如生活周期观察、单因子杂交、单核苷酸多态性研究、RNA干扰(RNAi)实验等;对实验设置、操作要求、实验相关准备工作等进行了较为细致的描述,为线虫在高校遗传学实验教学中的应用提供了详实案例,可为线虫在高校遗传学实验或其他相关实验课程如细胞生物学实验、模式生物与发育生物学实验中的应用提供参考。     

秀丽隐杆线虫2型糖尿病模型研究进展

秀丽隐杆线虫是一种结构简单且与人类基因在功能上具有高度保守性的模式生物,因其特点鲜明,所以广泛应用于人类疾病研究中,并在2型糖尿病研究中备受关注。目前,2型糖尿病发病机制尚未完全明确,现有的治疗手段会对人体带来许多副作用。利用秀丽隐杆线虫建立2型糖尿病研究模型,与其他2型糖尿病细胞模型和动物模型相比会带来不同的研究策略。本文综述了近年国内外秀丽隐杆线虫模型在2型糖尿病中相关研究进展,为后续研究提供理论参考。     

铜对秀丽隐杆线虫毒性效应的研究

为了阐明铜(Cu)对秀丽隐杆线虫Caenorhabditis elegans长期作用的毒性效应,对实验室多代筛选的耐铜型秀丽隐杆线虫进行了寿命、衰老、发育、生殖和运动等生物学指标的研究.结果显示耐铜型秀丽隐杆线虫与野生型秀丽隐杆线虫相比其寿命缩短、衰老提前、个体发育受到抑制,且出现繁殖率降低、生殖能力减弱、运动行为存在障碍等一系列生理变化.本文为理解与阐明Cu的毒性效应提供了实验资料,有助于深入开展Cu毒性机理的研究.     

秀丽隐杆线虫模型在阿尔茨海默病研究中的应用

阿尔茨海默病（Alzheimer’s disease,AD）是一种与年龄相关的神经退行性疾病,该疾病的病理特征为老年斑（SPs）和神经原纤维缠结（NFTs）的存在。目前,阿尔茨海默病患病率呈现逐年上升的趋势,寻找完全治愈或延缓阿尔茨海默症发展的有效疗法和药物迫在眉睫。秀丽隐杆线虫（Caenorhabditis elegans）的基因和神经元功能与人类具有高度同源性,可作为研究阿尔茨海默病发病机制研究的较好模型。本文综述AD的发病机制假说、秀丽隐杆线虫AD模型以及线虫模型在AD治疗中的应用进展,旨在为后续研究AD提供理论参考。     

A Lipid Droplet-Associated GFP Reporter-Based Screen Identifies New Fat Storage Regulators in C.elegans

Fat storage disorders including obesity are pandemic human health problems. As a genetically amenable model organism, Caeno- rhabditis elegans has often been used to explore the molecular mechanisms of fat storage regulation. Dye staining of fixed animals and stimulated Raman scattering （SRS） microscopy methods have been used successfully to study fat storage, but a genetic screening system that takes full advantage of C. elegans transparency to perform live imaging of fluorescent protein reporters has not yet been reported. Here, we investigated the tissue-specific expression of the GFP fusion of Perilipin 1 （PLIN1）, a Drosophila lipid droplet-associated protein, in C. elegans. Our results indicate that PLINI：：GFP labels lipid droplets and can be used as a fat storage indicator in live worms. Through an RNAi screen, we further identified several previously uncharacterized new fat storage regulators.     

Using C. elegans for aging research

Over a century ago, the zoologist Emile Maupas first identified the nematode, Rhabditis elegans, in the soil in Algiers. Subsequent work and phylogenic studies renamed the species Caenorhabditis elegans or more commonly referred to as C. elegans; (Caeno meaning recent; rhabditis meaning rod; elegans meaning nice). However, it was not until 1963, when Sydney Brenner, already successful from his work on DNA, RNA, and the genetic code, suggested the future of biological research lay in model organisms. Brenner believed that biological research required a model system that could grow in vast quantities in the lab, were cheap to maintain and had a simple body plan, and he chose the nematode C. elegans to fulfill such a role. Since that time, C. elegans has emerged as one of the premiere model systems for aging research. This paper reviews some initial identification of mutants with altered lifespan with a focus on genetics and then discusses advantages and disadvantages for using C. elegans as a model system to understand human aging. This review focuses on molecular genetics aspects of this model organism.     

The mystery of C. elegans aging: An emerging role for fat

New C. elegans studies imply that lipases and lipid desaturases can mediate signaling effects on aging. But why might fat homeostasis be critical to aging? Could problems with fat handling compromise health in nematodes as they do in mammals? The study of signaling pathways that control longevity could provide the key to one of the great unsolved mysteries of biology: the mechanism of aging. But as our view of the regulatory pathways that control aging grows ever clearer, the nature of aging itself has, if anything, grown more obscure. In particular, focused investigations of the oxidative damage theory have raised questions about an old assumption: that a fundamental cause of aging is accumulation of molecular damage. Could fat dyshomeostasis instead be critical?     

细菌介导的RNA干扰对C.elegans中par-3基因的作用

设计并构建了针对par-3基因的发夹RNA载体，将构建好的质粒转入大肠杆菌HT115，25℃喂食Caenorhabditis elegans（C.elegans）野生型虫体，24h后观察par-3（RNA干扰）celegans的胚胎发育情况。结果显示通过喂食形成发夹结构dsRNA的细菌可以对celegans中par-3基因进行RNA干扰，干扰率可以达到60％以上。干扰后的早期胚胎发育丧失第一次卵裂的不对称性，第二次卵裂的纺锤体方向发生改变，与par-3突变体的观察结果一致，为进一步在mex-3转基因虫体中通过RNA干扰研究基因表达打下了基础。     

Using C. elegans notch mutants in an undergraduate cancer biology laboratory course to demonstrate oncogenic effects on cell proliferation

Undergraduate laboratory exercises addressing aspects of cancer biology such as increased cell proliferation, gain-of-function signaling mutations and tumour formation often rely on tissue culture or even small mammal models. Many departments have limited or no access to these tools, and even well-equipped departments face logistical problems when incorporating these models into laboratory classes. I have developed a laboratory exercise using the microscopic worm, C. elegans, to demonstrate the effects of Notch receptor mutations on cell proliferation. Notch, which is activated by juxtacrine signaling, is mutated in many human cancers. In this exercise, students compare the germline phenotypes of worms that have a loss-of-function Notch mutation (no cells in the germline) or a gain-of-function Notch mutation (over-proliferation resulting in a germline tumour). Students also genotype the worms and perform sequence analysis to determine the effects of the mutations on the protein sequence. This laboratory exercise demonstrates oncogenic proliferation, correlates genotype to phenotype, exposes students to model organisms and introduces sequence databases and analysis. In addition to cancer biology courses, this exercise could be incorporated in courses with a focus on genetics, cell biology or developmental biology.     

Autophagy genes are required for normal lipid levels in C. elegans

Autophagy is a cellular catabolic process in which various cytosolic components are degraded. For example, autophagy can mediate lipolysis of neutral lipid droplets. In contrast, we here report that autophagy is required to facilitate normal levels of neutral lipids in C. elegans. Specifically, by using multiple methods to detect lipid droplets including CARS microscopy, we observed that mutants in the gene bec-1 (VPS30/ATG6/BECN1), a key regulator of autophagy, failed to store substantial neutral lipids in their intestines during development. Moreover, loss of bec-1 resulted in a decline in lipid levels in daf-2 [insulin/IGF-1 receptor (IIR) ortholog] mutants and in germline-less glp-1/Notch animals, both previously recognized to accumulate neutral lipids and have increased autophagy levels. Similarly, inhibition of additional autophagy genes, including unc-51/ULK1/ATG1 and lgg-1/ATG8/MAP1LC3A/LC3 during development, led to a reduction in lipid content. Importantly, the decrease in fat accumulation observed in animals with reduced autophagy did not appear to be due to a change in food uptake or defecation. Taken together, these observations suggest a broader role for autophagy in lipid remodeling in C. elegans.     

Endocytosis and intracellular trafficking contribute to necrotic neurodegeneration in C. elegans

Unlike apoptosis, necrotic cell death is characterized by marked loss of plasma membrane integrity. Leakage of cytoplasmic material to the extracellular space contributes to cell demise, and is the cause of acute inflammatory responses, which typically accompany necrosis. The mechanisms underlying plasma membrane damage during necrotic cell death are not well understood. We report that endocytosis is critically required for the execution of necrosis. Depletion of the key endocytic machinery components dynamin, synaptotagmin and endophilin suppresses necrotic neurodegeneration induced by diverse genetic and environmental insults in C. elegans. We used genetically encoded fluorescent markers to monitor the formation and fate of specific types of endosomes during cell death in vivo. Strikingly, we find that the number of early and recycling endosomes increases sharply and transiently upon initiation of necrosis. Endosomes subsequently coalesce around the nucleus and disintegrate during the final stage of necrosis. Interfering with kinesin-mediated endosome trafficking impedes cell death. Endocytosis synergizes with autophagy and lysosomal proteolytic mechanisms to facilitate necrotic neurodegeneration. These findings demonstrate a prominent role for endocytosis in cellular destruction during neurodegeneration, which is likely conserved in metazoans.     

线虫荧光标记稳定表达系的建立

目的:建立稳定表达的PHluorin标记的线虫种系,为囊泡在线虫ALA神经元上分泌机制的研究提供模型。方法:采用了国际先进的线虫转基因技术,将构建的Pida-1IDA-1:PHluorin质粒通过显微注射到线虫的母代,通过筛选后得到稳定表达的种系。结果:通过DIC显微镜整体检测和全内反射荧光成像技术(Tirfm)细胞检测,蛋白表达的位置正确,通过高倍数体式显微镜确定稳定种系中阳性率高达99%。结论:建立了一个稳定表达的荧光标记线虫种系,为进一步在线虫上研究囊泡分泌提供了很好的模型。     

Determining Genetic Expression Profiles in C. elegans Using Microarray and Real-time PCR

Synapses are composed of a presynaptic active zone in the signaling cell and a postsynaptic terminal in the target cell. In the case of chemical synapses, messages are carried by neurotransmitters released from presynaptic terminals and received by receptors on postsynaptic cells. Our previous research in Caenorhabditis elegans has shown that VSM-1 negatively regulates exocytosis. Additionally, analysis of synapses in vsm-1 mutants showed that animals lacking a fully functional VSM-1 have increased synaptic connectivity. Based on these preliminary findings, we hypothesized that C. elegans VSM-1 may play a crucial role in synaptogenesis. To test this hypothesis, double-labeled microarray analysis was performed, and gene expression profiles were determined. First, total RNA was isolated, reversely transcribed to cDNA, and hybridized to the DNA microarrays. Then, in-silico analysis of fluorescent probe hybridization revealed significant induction of many genes coding for members of the major sperm protein family (MSP) in mutants with enhanced synaptogenesis. MSPs are the major component of sperm in C. elegans and appear to signal nematode oocyte maturation and ovulation . In fruit flies, Chai and colleagues ¹ demonstrated that MSP-like molecules regulate presynaptic bouton number and size at the neuromuscular junction. Moreover, analysis performed by Tsuda and coworkers ² suggested that MSPs may act as ligands for Eph receptors and trigger receptor tyrosine kinase signaling cascades. Lastly, real time PCR analysis corroborated that the gene coding for MSP-32 is induced in vsm-1(ok1468) mutants. Taken together, research performed by our laboratory has shown that vsm-1 mutants have a significant increase in synaptic density, which could be mediated by MSP-32 signaling.     

Transformer基因与果蝇和线虫的性别决定

黑腹果蝇(Drosophila melanogaster)和秀丽隐杆线虫（Caeborhabditis elegans）的性别决定的问题已研究得比较详细,且transformer基因是这两种生物性别决定中最重要的基因之一,其有关的性别决定研究在近几年取得了很大的进展。本文就线虫和果蝇的transformer基因及其相关基因的特性与功能进行了特别介绍,并在此基础上对其性别决定的分子机制进行初步的比较和分析。Abstract : Sex determination of Drosophila melanogaster and Caeborhabditis elegans has been known in detail. Great progress, is achieved in recent years, is the research of transformer genes, which are those of most important genes in sex determination in both species. In this paper, molecular character, genetic function and the relative genes of transformer genes are particularly described. On the basis,a primary compariso and analysis between the molecular mechanism of sex determination in C.elegans and D. melanogaster are presented.