单细胞凝胶电泳技术及在土壤生态毒理学中的应用

单细胞凝胶电泳技术又称为彗星实验,是最近几年发展起来的一种快速、简单、灵敏、可靠的检测细胞核DNA损伤的技术。总结了近几年来单细胞凝胶电泳技术的发展、原理、方法及其应用,并指出其下一步的发展趋势。彗星实验中,镶嵌于琼脂糖中的细胞核在电场中向正极移动,因细胞核与DNA片段迁移速率不同,而形成类似“彗星”的图像。目前采用的彗星实验有多种,可以检测诸如DNA双链断裂、单链断裂、碱不稳定位点等多种类型的DNA损伤。碱性彗星实验因其高灵敏度而被广泛采用。彗星实验的主要步骤包括细胞核悬浮液的获得、彗星电泳胶板制备、细胞裂解、DNA变性解旋、电泳、中和、染色和观察等。目前彗星实验广泛应用于各个研究领域,近年来开始用于环境污染的基因毒性研究和生物监测,并取得了迅速发展。     

应用蝌蚪快速检测环境变异的两种方法--微核试验和单细胞凝胶电泳

本文介绍了应用无尾两栖类动物的蝌蚪进行环境监测的两种方法——微核试验和单细胞凝胶电泳。此两种环境检测的方法与其他环境检测方法相比具有快速,简便,易操作,适于检测现场应用,可大面积推广等优点。     

单细胞测序技术及其在传染病研究领域中的应用

单细胞测序技术是在单个细胞水平上对基因组或者转录组进行测序,从而分析相同表型细胞的遗传异质性,或获得难以培养微生物的遗传信息。单细胞测序技术的应用已经深刻地改变了我们对一系列生物学现象的理解,包括基因转录、胚胎发育、癌变。对单细胞测序技术的方法和应用进行了概述,并对其在传染病研究中的应用进行了详细介绍。     

微生物单细胞分离方法研究进展

自然界中大多数微生物处于未培养状态,被称为“微生物暗物质”。随着微生物单细胞分离方法的不断更新,利用新技术、新方法应对微生物纯培养的挑战获得了重要进展,这些新的分离及培养策略对推动微生物资源学的发展具有重要意义。尽管宏基因组学和基因组学数据相关成果日益增多,但微生物单细胞的分离与培养对于系统研究微生物的生态功能、遗传进化等仍至关重要。本文主要概述了目前使用的或正在研发的膜扩散培养法、微流控分选、荧光激活细胞分选、单细胞拉曼分选、光镊技术、显微操作技术等单细胞分离技术的原理与应用,及其在微生物单细胞分离和培养方面的优点与不足,同时展望了这些单细胞分离技术未来的发展和应用前景。     

解脂耶罗维亚酵母产油脂的研究进展

单细胞油脂是生产生物柴油最理想的原料,随着化石能源的日益枯竭,单细胞油脂的生产受到广泛关注。解脂耶罗维亚酵母是生产单细胞油脂的最佳菌株,它能够利用诸多廉价底物作为碳源,在工业上有极大的应用前景。其遗传背景清晰,全基因组测序已完成,基因表达系统已构建。在此基础上对油脂累积途径进行了深入研究,多株油脂含量更高的菌株被构建。深入了解解脂耶罗维亚酵母的基因表达及油脂代谢系统,对日后对其进一步的代谢改造具有重要意义。     

单细胞转录组测序技术新进展及其在造血系统研究中的应用

单细胞测序技术凭借其能全面反映细胞群体异质性这一优势,近年来发展迅速.其中,单细胞转录组测序技术提供了在分子水平上对细胞作分类或表征的替代方法,在发育生物学、神经科学、血液学、免疫及癌症等研究领域均展示出了广泛的应用前景.本文总结了近年来单细胞转录组测序技术的主要发展趋势,并列举了该技术在造血系统中的应用.     

DNA断裂检测方法──单细胞凝胶电泳法

单细胞凝胶电泳(single cell gel electrophoresis assay,SCGE)也叫彗星试验(comet assay),是一种快速、敏感、简便、廉价的检测单个哺乳动物细胞DNA断裂的技术,目前已用于检测氧化、紫外线和电离辐射引起的损伤,以及三氯乙烷、丙烯酰胺等化学物及老化、吸烟所致损害的研究.文章介绍SCGE的发展、检测分析方法、原理及其在DNA损伤与修复、生物监测、遗传毒理研究、肿瘤治疗方案优化和疗效研究方面的应用前景．     

单细胞拉曼光谱在微生物研究中的应用

拉曼显微光谱是一种能够提供0.5–1.0μm空间分辨率的单个微生物细胞内化学结构信息的研究技术。近几年来,拉曼显微光谱被越来越多地应用于微生物单细胞的研究中,它可以快速无损地检测微生物细胞内的特征化学组分。典型的单个微生物细胞的拉曼光谱包含核酸、蛋白质、碳水化合物、脂质和色素(例如类胡萝卜素)等信息,这些信息能够表征微生物细胞的基因型、表型和生理状态。所以单细胞拉曼显微光谱是一种可用于区分微生物样品的"全生物指纹"技术,它可用于研究单个微生物细胞生命阶段的转变、鉴定微生物单细胞中的色素及其他化合物的含量变化等。本文综述了目前拉曼显微光谱在微生物单细胞研究上的应用,主要包括与稳定同位素标记(stable isotope probing,SIP)、拉曼成像、光谱分类和细胞分选技术结合来探究微生物单细胞对物质吸收后特征峰的变化、推导物质循环过程、进行微生物分类鉴定和探索基因型与表型的关系。拉曼显微光谱作为微生物单细胞研究的手段之一,在代谢过程的研究、活细胞分选和细胞对物质的利用上具有广泛的应用前景。     

稀土元素的生物安全性探讨

采用微核检测、单细胞凝胶电泳、同工酶等技术研究了稀土元素遗传毒理效应的有关结果。大量试验表明,稀土元素断裂DNA的能力,因而在一定浓度范围内,稀土元素确有致突变性。稀土元素在土壤中可专性吸附、不可降解,在动植物和人体皆有累积效应,因此稀土元素的生物安全性值得深入探讨。     

酵母菌质粒遗传研究进展

酵母菌做为真核微生物的代表已被广泛应用于分子遗传学研究。酵母菌除具备真核生物所共有的生物学特性外,它又是单核单细胞生物。因此凡是细菌分子遗传学研究中所使用的技术。基本上都适用于酵母菌的分子遗传研究。酵母菌质粒的分子遗传学在最近     

Detection of biotinylated proteins in polyacrylamide gels using an avidin-fluorescein conjugate

Biotinylated proteins are widely used as a molecular tool in biotechnological applications. In this paper, we demonstrated that biotinylated proteins after electrophoresis were detected directly in gels using an avidin-fluorescein conjugate with a fluorescence image analyzer. Upon analysis of the purified and chemically biotinylated protein, the sensitivity of this method was almost equal to that of silver staining. Chemically biotinylated proteins of Escherichia coli cell surfaces could also be specifically detected with our method. Furthermore, recombinant proteins fused with the biotin acceptor domain and biotinylated enzymatically in vivo were also detected in a lysate of E. coli specifically. The sensitivity and specificity of our method are high, and the procedure is simple. Therefore, our method would benefit detection of biotinylated proteins via gel electrophoresis and also various fields of study using avidin-biotin technology.     

Electrophoresis today and tomorrow: Helping biologists' dreams come true

Intensive research and development of electrophoresis methodology and instrumentation during past decades has resulted in unique methods widely implemented in bioanalysis. While two‐dimensional electrophoresis and denaturing polyacrylamide gel electrophoresis in sodium dodecylsulfate are still the most frequently used electrophoretic methods applied to analyses of proteins, new miniaturized capillary and microfluidic versions of electromigrational methods have been developed. High‐throughput electrophoretic instruments with hundreds of capillaries for parallel separations and laser‐induced fluorescence detection of labeled DNA strands have been of key importance for the scientific and commercial success of the Human Genome Project. Another powerful method, capillary isoelectric focusing with pressurized and pH‐driven mobilization, provides efficient separations and on‐line sensitive detection of proteins, bacteria and viruses. Electrophoretic microfluidic devices can integrate single‐cell injection, cell lysis, separation of its components and fluorescence or mass spectrometry detection. These miniaturized devices also proved the capability of single‐molecule detection.     

Single cell gel electrophoresis assay: methodology and applications

The single cell gel electrophoresis or Comet assay is a sensitive, reliable, and rapid method for DNA double- and single-strand breaks, alkali-labile sites and delayed repair site detection, in eukariotic individual cells. Given its overall characteristics, this method has been widely used over the past few years in several different areas. In this paper we review the studies published to date about the principles, the basic methodology with currently used variations. We also explore the applications of this assay in: genotoxicology, clinical area, DNA repair studies, environmental biomonitoring and human monitoring.     

All about DIGE: quantification technology for differential-display 2D-gel proteomics

2D polyacrylamide gel electrophoresis has been the traditional workhorse of proteomics, allowing for the resolution of several thousand proteins in a single gel. Difference gel electrophoresis is an emerging technology that allows for accurate quantification with statistical confidence while controlling for nonbiologic variation, and also increases the dynamic range and sensitivity of traditional 2D polyacrylamide gel electrophoresis. With inclusion of an internal standard formed from equal amounts of every sample in an experiment, difference gel electrophoresis technology also allows for repetitive measurements and multivariable analyses to be quantitatively analyzed in one co-ordinated experiment, yielding statistically-significant changes in protein expression related to many disease states. This technique promises to be an important tool in clinical proteomics and the study of the mechanism of disease, investigating diagnostic biomarkers and pinpointing novel therapeutic targets.     

All about DIGE: quantification technology for differential-display 2D-gel proteomics

2D polyacrylamide gel electrophoresis has been the traditional workhorse of proteomics, allowing for the resolution of several thousand proteins in a single gel. Difference gel electrophoresis is an emerging technology that allows for accurate quantification with statistical confidence while controlling for nonbiologic variation, and also increases the dynamic range and sensitivity of traditional 2D polyacrylamide gel electrophoresis. With inclusion of an internal standard formed from equal amounts of every sample in an experiment, difference gel electrophoresis technology also allows for repetitive measurements and multivariable analyses to be quantitatively analyzed in one co-ordinated experiment, yielding statistically-significant changes in protein expression related to many disease states. This technique promises to be an important tool in clinical proteomics and the study of the mechanism of disease, investigating diagnostic biomarkers and pinpointing novel therapeutic targets.     

An improved sample preparation method for analyzing mycobacterial proteins in two-dimensional gels

Two-dimensional gel electrophoresis (2-DE) is currently a widely used analytical method for resolving complex mixtures of proteins. Sample preparation has a marked influence on 2-DE pattern. To reduce impurities and to increase the low-abundance proteins, protein precipitation is often used for the preparation of samples before 2-DE. In this study, we revealed that addition of SDS prior to TCA precipitation of mycobacterial cell extract proteins increases the resolution of the 2-D gel pattern.     

Sub-proteome differential display: single gel comparison by 2D electrophoresis and mass spectrometry

Two-dimensional (2D) gel electrophoresis and mass spectrometry (MS) have been used in comparative proteomics but inherent problems of the 2D electrophoresis technique lead to difficulties when comparing two samples. We describe a method (sub-proteome differential display) for comparing the proteins from two sources simultaneously. Proteins from one source are mixed with radiolabelled proteins from a second source in a ratio of 100:1. These combined proteomes are fractionated simultaneously using column chromatographic methods, followed by analysis of the pre-fractionated proteomes (designated sub-proteomes) using 2D gel electrophoresis. Silver staining and (35)S autoradiography of a single gel allows precise discrimination between members of each sub-proteome, using commonly available computer software. This is followed by MS identification of individual proteins. We have demonstrated the utility of the technology by identifying the product of a transfected gene and several proteins expressed differentially between two renal carcinoma proteomes. The procedure has the capacity to enrich proteins prior to 2D electrophoresis and provides a simple, inexpensive approach to compare proteomes. The single gel approach eliminates differences that might arise if separate proteome fractionations or 2D gels are employed.     

单细胞测序方法研究进展

近年来,高通量测序技术(Next-generation sequencing,NGS)快速发展,已广泛应用于生命科学各个领域,但传统的混合细胞测序(Bulk cell sequencing)检测的是细胞群体的总平均反应,无法反应每个细胞的真实情况,这会影响研究者对细胞功能认知的准确性。单细胞测序技术(Single cell sequencing,sc-Seq)的出现,从一定程度上解决了传统测序固有的缺陷。单细胞测序是针对单个细胞的RNA或DNA进行测序,能够准确测出单个细胞的基因结构和表达状态,从而分析相同表型细胞的异质性。本文首先介绍单细胞测序的原理、测序类型和测序平台,有助于理解单细胞测序和在进行科研项目时设计合适的项目方案。进一步介绍单细胞转录组测序的分析流程和各种常用的分析工具或软件,并重点阐述单细胞转录组测序分析中的细胞聚类和拟时序分析的原理和研究进展,为进行单细胞转录组测序数据分析提供参考。最后,本文简述了单细胞测序研究热度、单细胞测序的应用、挑战和展望等,有助于更全面地认识单细胞测序。     

DGGE技术在环境微生物多样性研究中的应用

微生物是污水净化的主要作用者之一.采用变性梯度凝胶电泳(denaturing gradient gel electrophresis,DGGE)方法培育和鉴定土壤微生物具有可靠性强、重复性好、方便快捷等优点,已被广泛应用于环境科学和污染防治研究领域.综述了基于PCR-DGGE技术的基本原理、关键环节及其在微生物多样性研究中的应用,同时就其自身存在的不足进行了评价并提出了解决方案.