Single‐Cell Sorting of Microorganisms by Flow or Slide‐Based (Including Laser Scanning) Cytometry

In applied microbiology, strain improvement of microorganisms by conventional selection culture is not always successful, so single‐cell selection of viable cells with the desired characteristics from a large heterogeneous population may be used instead. Single‐cell selection with use of a micromanipulator is possible, but laborious. For many applications, the process has been automated. In this review, an automated method, laser scanning cytometry (LSC), is outlined together with flow cytometry (FCM). FCM is familiar to many microbiologists, but LSC is a microscopic‐slide‐based method that is less well known. One of its advantages is its possible use in the examination of small cell populations.In addition, individual cells can be examined repeatedly, measured automatically and later observed microscopically by the operator, and finally stored (if desired)on the microscopic slide on which they are placed. Fluorescent and other probes are available in abundance for FCM, and almost all might be used in LSC. A number of applications of these methods are cited from the extensive literature (mostly about FCM), but the list of possible applications in this review is far from being exhaustive. This review is intended as an introduction for the applied microbiologist to the manifold uses of LSC.     

The potential of flow cytometry in the study of Bacillus cereus

Flow cytometry (FCM) is a rapid method allowing the acquisition of multiparametric data from thousands of individual cells within a sample. As well as measuring the intrinsic light scattering properties of cells, a plethora of fluorescent dyes may be employed to yield information on macromolecule content, surface antigens present or physiological status. Despite FCM's indispensability within other fields e.g. immunology, it is underutilized within microbiological research. In this review, a strong case is presented for the potential of FCM in the study of Gram-positive spore-former, Bacillus cereus . Previous reports where FCM was successfully used in the study of B. cereus are reviewed along with relevant studies involving other members of the genus. Under headings reflecting common research themes associated with B. cereus , specific instances where FCM has generated novel data, providing a unique insight into the organism, are discussed. Further applications are posited, based on the authors' own research with FCM and B. cereus and work extant in the broader field of microbial cytometry. The authors conclude that, while the expense of equipment and reagents is an undeniable disadvantage, FCM is a technique capable of generating significantly novel data and allows the design and execution of experiments that are not possible with any other technique.     

The relevance of flow cytometry for biochemical analysis

Flow cytometry (FCM) allows the simultaneous measurement of multiple fluorescences and light scatter induced by illumination of single cells or microscopic particles in suspension, as they flow rapidly through a sensing area. In some systems, individual cells or particles may be sorted according to the properties exhibited. By using appropriate fluorescent markers, FCM is unique in that multiple structural and functional parameters can be quantified simultaneously on a single-particle basis, whereas up to thousands of biological particles per second may be examined. FCM is increasingly used for basic, clinical, biotechnological, and environmental studies of biochemical relevance. In this critical review, we summarize the main advantages and limitations of FCM for biochemical studies and discuss briefly the most relevant parameters and analytical strategies. Graphical examples of the biological information provided by multiparametric FCM are presented. Also, this review contains specific sections on flow cytoenzymology, FCM analysis of isolated subcellular organelles, and cell-free FCM.     

流式细胞术分析和分拣植物染色体

流式细胞术是当染色体、细胞核和细胞等颗粒随着流动的液体（水或缓冲液）通过一个测量点时,被探测器探测到,这样根据颗粒的物理和化学特征而将不同的颗粒分开并计数分拣的技术。流式细胞分析在人类基因组计划中发挥了重要作用,流式细胞技术的应用也适用于植物,目前这个技术应用范围包括流式核型分析,分拣纯化染色体,定位基因,构建文库等。文章综述了流式细胞术在植物基因组分析方面的研究进展。     

Routine monitoring of Cryptosporidium oocysts in water using flow cytometry

A flow cytometric method for the routine analysis of environmental water samples for the presence of Cryptosporidium oocysts has been developed. It uses a Coulter Epics Elite flow cytometer to examine water samples and to separate oocysts from contaminating debris by cell sorting. The sorted particles are then rapidly screened by microscopy. The method has been evaluated and compared with direct epifluorescence microscopy on 325 river, reservoir and drinking water samples. The technique was found to be more sensitive, faster and easier to perform than conventional epifluorescent microscopy for the routine examination of water samples for Cryptosporidium.     

Flow cytometry in oceanography 1989--1999: environmental challenges and research trends.

BACKGROUND: The present review is based on the identification of four major environmental crises that have been approached from a biological oceanographic viewpoint. These crises are the release of contaminants in near shore marine waters, the collapse of marine resources that were renewable until recently, the loss of biodiversity, and global climate change METHODS: The review examines the contribution of cytometry-based biological oceanography to the resolution of the four environmental crises. Using a database of 302 papers, flow cytometric (FCM) studies in biological oceanography over the 1989--1999 decade are examined. Future biological oceanographic applications of FCM are discussed. RESULTS: Most of the published FCM oceanographic studies focus on phytoplankton and bacterioplankton. Analysis of our 1989-1999 database shows the predominance of studies dedicated to phytoplankton (77%), followed by heterotrophic bacteria (21%). The latter progressively increased over the last decade, together with the improved understanding of the biogeochemical and trophic roles of marine bacteria. Most studies on these two microorganisms were conducted in vitro until 1996, after which the trend reversed in favor of in situ research. The most investigated areas were those with major international sampling efforts, related to the changing climate. Concerning environmental topics, 62% of papers on phytoplankton and bacterioplankton focused on the structure of microbial communities and fluxes (e.g., production, grazing); this provides the basis for biological oceanographic studies on resources and climate change. CONCLUSIONS: Future progress in the biological oceanographic use of FCM will likely fall into two categories, i.e., applications where FCM will be combined with the development of other methods and those where FCM will be the main analytical tool. It is expected that FCM and other cytometric approaches will improve the ability of biological oceanography to address the major environmental challenges that are confronting human societies.     

Flow cytometry in cytopathology. Overview and perspectives

The future applications of flow cytometry (FCM) are briefly discussed. Whereas the early goals of its clinical applications were cancer diagnosis and classification, it has now become apparent that FCM can more successfully provide information on a variety of cell constituents of crucial importance in the evaluation of tumor prognosis and treatment sensitivity. It is suggested that (1) the data being provided by FCM will probably lead to a more clinically relevant classification of tumors, based more on the biochemical/molecular markers of individual cells and an assessment of tumor heterogeneity and less on classical cell morphology and tumor progression, and (2) FCM seems likely to become established as a routine methodology in cytopathology.     

T_RFLP技术及其在硝化细菌群落分析中的应用

T_RFLP是建立在PCR基础上的, 一种不依赖于传统培养方法的微生物生态学的研究方法。具有快速、灵敏的特点。自1997年首次被报道以来, T_RFLP技术已广泛应用于菌种鉴定、群落对比分析、群落中系统发育种群多样性的评估等领域, 并成为环境微生物群落结构分析的强有力工具之一。目前T_RFLP在国内的应用较少, 硝化细菌的群落分析上还未见报道。但作为一种研究微生物群落结构特征的理想方法, 将会得到广泛地应用。本文主要介绍了T_RFLP的基本原理, 概括了在微生物群落分析上的应用, 阐述了硝化细菌传统研究的局限性及T_RFLP在硝化细菌群落结构分析上的应用前景。     

T_RFLP技术及其在硝化细菌群落分析中的应用

T_RFLP是建立在PCR基础上的,一种不依赖于传统培养方法的微生物生态学的研究方法.具有快速、灵敏的特点.自1997年首次被报道以来,T_RFLP技术已广泛应用于菌种鉴定、群落对比分析、群落中系统发育种群多样性的评估等领域,并成为环境微生物群落结构分析的强有力工具之一.目前T_RFLP在国内的应用较少,硝化细菌的群落分析上还未见报道.但作为一种研究微生物群落结构特征的理想方法,将会得到广泛地应用.本文主要介绍了T_RFLP的基本原理,概括了在微生物群落分析上的应用,阐述了硝化细菌传统研究的局限性及T_RFLP在硝化细菌群落结构分析上的应用前景.     

流式细胞术在细菌快速检测中的应用

流式细胞仪(Flow cytometer)是集应用流体学、光学、电子学、生物学、免疫学等多门学科和技术于一体的新型高科技仪器。它的核心技术是流式细胞术(Flow cytometry,FCM),该技术是利用流式细胞仪,使单个细胞或其他微小生物粒子处于快速直线流动状态,且逐个通过光束,从而对单个细胞或微粒进行多参数(数量、大小、核酸含量、细胞活性、特定菌群或物种等)定量分析和分选的检测技术,具有快速、灵敏、精确以及便于操作等突出优点。本文简要介绍流式细胞仪的原理,并论述流式细胞技术在实验室研究、工业生产、临床诊断、环境评估等领域的细菌快速检测应用。     

微细胞介导的染色体转移技术及其应用

微细胞介导的染色体转移技术（MMCT）是一项利用微细胞将外源染色体转入受体细胞的技术。该技术是在细胞融合的基础之上发展起来的,是细胞融合技术的进一步细化,在当代生物的若干领域里得到了广泛的应用。～些肿瘤抑制基因、端粒酶抑制基因、诱导衰老基因以及DNA修复基因都是通过MMCT技术取得细胞内识别和定位,由此促进了针对这些基因的功能研究,并为相关疾病的治疗提供了依据。同时,MMcT技术也为其他领域如表观遗传学、基因组印迹、哺乳动物人工染色体等方面的进一步研究提供了有力的手段。与体细胞核移植技术结合,MMCT还可用于建立具有重要医学药用价值和优良农业生产性状的转染色体动物,显示其具有广阔的应用前景。本文概述了MMCT技术及其在相关领域的应用与发展趋势。     

Display of proteins on bacteria

Display of heterologous proteins on the surface of microorganisms, enabled by means of recombinant DNA technology, has become an increasingly used strategy in various applications in microbiology, biotechnology and vaccinology. Gram-negative, Gram-positive bacteria, viruses and phages are all being investigated in such applications. This review will focus on the bacterial display systems and applications. Live bacterial vaccine delivery vehicles are being developed through the surface display of foreign antigens on the bacterial surfaces. In this field, 'second generation' vaccine delivery vehicles are at present being generated by the addition of mucosal targeting signals, through co-display of adhesins, in order to achieve targeting of the live bacteria to immunoreactive sites to thereby increase immune responses. Engineered bacteria are further being evaluated as novel microbial biocatalysts with heterologous enzymes immobilized as surface exposed on the bacterial cell surface. A discussion has started whether bacteria can find use as new types of whole-cell diagnostic devices since single-chain antibodies and other type of tailor-made binding proteins can be displayed on bacteria. Bacteria with increased binding capacity for certain metal ions can be created and potential environmental or biosensor applications for such recombinant bacteria as biosorbents are being discussed. Certain bacteria have also been employed for display of various poly-peptide libraries for use as devices in in vitro selection applications. Through various selection principles, individual clones with desired properties can be selected from such libraries. This article explains the basic principles of the different bacterial display systems, and discusses current uses and possible future trends of these emerging technologies.     

Luminescence-Based Systems for Detection of Bacteria in the Environment

Abstract

The development of techniques for detection and tracking of microorganisms in natural environments has been accelerated by the requirement for assessment of the risks associated with environmental release of genetically engineered microbial inocula. Molecular marker systems are particularly appropriate for such studies and luminescence-based markers have the broadest range of applications, involving the introduction of prokaryotic (lux) or eukaryotic (luc) genes for the enzyme luciferase.

Lux or luc genes can be detected on the basis of unique DNA sequences by gene probing and PCR amplification, but the major advantage of luminescence-based systems is the ability to detect light emitted by marked organisms or by luciferase activity in cell-free extracts. Luminescent colonies can be detected by eye, providing distinction from colonies of indigenous organisms, and the sensitivity of plate counting can be increased greatly by CCD imaging. Single cells or microcolonies of luminescent organisms can also be detected in environmental samples by CCD image-enhanced microscopy, facilitating study of their spatial distribution. The metabolic activity of luminescence-marked populations can be quantified by luminometry and does not require extraction of cells or laboratory growth. Metabolic activity, and potential activity, of marked organisms therefore can be measured during colonization of soil particles and plant material in real time without disturbing the colonization process.

In comparison with traditional activity techniques, luminometry provides significant increases in sensitivity, accuracy, and, most importantly, selectivity, as activity can be measured in the presence of indigenous microbial communities. The sensitivity, speed, and convenience of luminescence measurements make this a powerful technique that is being applied to the study of an increasingly wide range of ecological problems. These include microbial survival and recovery, microbial predation, plant pathogenicity, phylloplane and rhizosphere colonization and reporting of gene expression in environmental samples.     

Application of a microcomputer-based algal fluorescence technique for assessing toxicity: Lake St. Clair and St. Clair River examples

The use of a multi-trophic assay strategy is now being encouraged in toxicological investigations which provides for rapid and sensitive tests. Such a strategy, a microcomputer-based algal fluorescence technique, was applied for the bioassessment of Lake St. Clair and St. Clair River ecosystems. The technique was found to be rapid, sensitive, and relatively inexpensive. In addition, it permitted microscopic examination of the impact of contaminants on individual cells/organisms, a feature which is not possible by other tests using radioisotopes and enzymes. The algal fluorescence technique appears to have a considerable potential for fast screening of large numbers of environmental samples.     

流式细胞仪在微型浮游植物生态学中的应用

微型浮游植物是水域生态系统中的初级生产者 ,是海洋生态系统存在的基础。习惯上浮游植物根据其粒径大小有分为小型浮游植物 (ｍｉｃｒｏ - ｐｈｙｔｏｐｌａｎｋｔｏｎ ,>2 0ｕｍ) ,微型浮游植物 (ｎａｎｏ - ｐｈｙｔｏｐｌａｎｋ ｔｏｎ ,<2 0ｕｍ ,>2ｕｍ )和超微型浮游植物( ｐｉｃｏ - ｐｈｙｔｏｐｌａｎｋｔｏｎ ,<2ｕｍ )三类[13 ] 。本文将后两类统称为微型浮游植物。在早期的多数研究中 ,检测技术和方法落后 :譬如测定水域中的生物量和叶绿素ａ含量常用的拖网方法 ,几乎丢失了所有的微型浮游植物 ;即使是实验室内常用 0 .45ｕｍ…     

Determination of bronchoalveolar lavage leukocyte populations by flow cytometry in patients investigated for respiratory disease

BACKGROUND: Characteristic changes in the proportions of leukocyte populations in bronchoalveolar lavage (BAL) reflect different disease states in the lung. The standard method for examination of BAL leukocytes is by microscopy of cytospin preparations. This method may not be the optimum technique due to difficulties in distinguishing cell types morphologically and due to the low number of cells routinely counted. We hypothesized that flow cytometry (FCM) may be a more precise tool for investigating BAL. METHODS: 100 BALs were performed on 92 patients. All samples were stained using the pan-leukocyte marker (CD45) in combination with a granulocyte marker (CD15) and a cell viability marker (7-aminoactinomycin D). Selected samples were also stained with an eosinophil marker (CD23). These samples were run on an FCM and the results compared with leukocyte differentials obtained by light microscopy of parallel cytospin preparations. RESULTS: Close correlations between the two methods were demonstrated for the enumeration of all leukocyte subsets, but the coefficient of variation was considerably lower by FCM than by cytospin. CONCLUSIONS: These findings, combined with the speed of FCM and the ability to perform simple lymphocyte phenotyping, argue in favor of this becoming the method of choice for investigating BAL.     

Two-dimensional gel electrophoresis in bacterial proteomics

Two-dimensional gel electrophoresis (2-DE) is a gel-based technique widely used for analyzing the protein composition of biological samples. It is capable of resolving complex mixtures containing more than a thousand protein components into individual protein spots through the coupling of two orthogonal biophysical separation techniques: isoelectric focusing (first dimension) and polyacrylamide gel electrophoresis (second dimension). 2-DE is ideally suited for analyzing the entire expressed protein complement of a bacterial cell: its proteome. Its relative simplicity and good reproducibility have led to 2-DE being widely used for exploring proteomics within a wide range of environmental and medically-relevant bacteria. Here we give a broad overview of the basic principles and historical development of gel-based proteomics, and how this powerful approach can be applied for studying bacterial biology and physiology. We highlight specific 2-DE applications that can be used to analyze when, where and how much proteins are expressed. The links between proteomics, genomics and mass spectrometry are discussed. We explore how proteomics involving tandem mass spectrometry can be used to analyze (post-translational) protein modifications or to identify proteins of unknown origin by de novo peptide sequencing. The use of proteome fractionation techniques and non-gel-based proteomic approaches are also discussed. We highlight how the analysis of proteins secreted by bacterial cells (secretomes or exoproteomes) can be used to study infection processes or the immune response. This review is aimed at non-specialists who wish to gain a concise, comprehensive and contemporary overview of the nature and applications of bacterial proteomics.     

Flow cytometry: instrumentation and application in phytoplankton research

In flow cytometry, light scattering and fluorescence of individual particles in suspension is measured at high speed. When applied to planktonic particles, the light scattering and (auto-)fluorescence properties of algal cells can be used for cell identification and counting. Analysis of the wide size spectrum of phytoplankton species, generally present in eutrophic inland and coastal waters, requires flow cytometers specially designed for this purpose. This paper compares the performance in phytoplankton research of a commercial flow cytometer to a purpose built instrument. It reports on the identification of phytoplankton and indicates an area where flow cytometry may supersede more conventional techniques: the analysis of morphological and physiological characteristics of subpopulations in phytoplankton samples.     

Flow cytometry for the development of biotechnological processes with microalgae

The current interest in microalgae as a sustainable source of next generation biofuels and other valuable substances is driving exploration of their use as unique biotechnological production systems. To design and optimise appropriate production strategies, the behaviour of particular microalgal species should be well characterised under different culture conditions. Thus, flow cytometric (FCM) methods, which are already well established in environmental and toxicological studies of microalgae, are also useful for analysing the physiological state of microalgae, and have the potential to contribute to the rapid development of feasible bioprocesses. These methods are commonly based on the examination of intrinsic features of individual cells within a population (such as autofluorescence or size). Cells possessing the desired physiological or morphological features, which are detectable with or without fluorescent staining, are counted or isolated (sorted) using an FCM device. The options for implementation of FCM in the development of biotechnological processes detailed in this review are (i) analysing the chemical composition of biomass, (ii) monitoring cellular enzyme activity and cell viability, and (iii) sorting cells to isolate those overproducing the target compound or for the preparation of axenic cultures.     

Electron microscopy of cells showing viral cytopathic effects in Papanicolaou smears

A technique is described whereby cells showing cytologic changes suggestive of virus infection by light microscopy can be processed further for examination in the electron microscope so that virus particles present in the cell can be visualized directly. We present the results of electron microscopy of over 100 Papanicolaou-stained smears processed this way. The morphologic changes in the cells and the ultrastructural appearances of the virus particles are demonstrated. This technique is particularly valuable for retrospective studies of mounted cytologic or histologic material. It has also proven to be a valuable research tool in the study of human polyomavirus and human wart virus infection.