Rapid assessment of bacterial viability by flow cytometry

The ability of a flow cytometer to rapidly assess microbial viability was investigated using three vital stains: rhodamine 123 (Rh123); 3,3'-dihexyloxacarbocyanine iodide [DiOC₆(3)] and fluorescein diacetate (FDA). Rh123 was found to clearly differentiate viable from non-viable bacteria. The methodology for staining bacteria with this dye was optimised. Rh123 was shown to stain and discriminate several different species of viable bacteria although this was not universal. Viable cells of Bacillus subtilis were found to stain better with FDAthan with Rh123. The results demonstrate the ability of flow cytometry to rapidly detect and estimate the viability of bacterial populations.Correspondence to: J. P. Diaper     

Evaluation of ChemChrome V6 for bacterial viability assessment in waters

The efficiency of ChemChrome B (CB) and ChemChrome V6 (CV6) dyes to stain viable bacterial cells in water was compared. Both dyes are fluorogenic esters converted to free fluorescein by esterase activity. The dyes were applied to a wide variety of bacterial species, including those poorly stained by CB, and to natural waters. Some species tested gave unacceptable low fluorescence intensities by being inefficiently or non-labelled with the CB. In contrast, CV6-stained bacteria were easily detected by both flow cytometry and solid-phase cytometry. As a consequence, higher viable cell counts were found with CV6 compared with CB in natural waters. Viable counts determined by CV6 staining were always higher than cfu counts. In contrast, respiring cell counts (CTC) were always lower than CV6 counts and, in the case of tap and mineral waters, they were lower than cfu counts.     

Increased growth yields of Mycoplasma spp. in the presence of pyruvate

Viable and non-viable African green monkey kidney (Vero) cells after treatment with Clostridium perfringens enterotoxin (CPE) followed by simultaneous double staining with fluorescein diacetate (FDA) and propidium iodide (PI) were counted with a flow cytometer (FCM). Within 1 min the FCM analysed 10 000 Vero cells in a sample for viability. After treatment of Vero cells with CPE for 60 min and staining with FDA-PI for 5 min, a reproducible dose-response curve was obtained between 25 and 400 ng/ml of CPE and percentage viable cell numbers. The FCM analysis proved to be a strong tool for rapid discrimination between viable and non-viable Vero cells treated with CPE in a large number of samples at a time.     

Targeted bulk-loading of fluorescent indicators for two-photon brain imaging in vivo

One of the challenges for modern neuroscience is to understand the rules of concerted neuronal function in vivo. This question can be addressed using noninvasive high-resolution imaging techniques like two-photon microscopy. This protocol describes a versatile approach for in vivo two-photon calcium imaging of neural networks, stained with membrane-permeant fluorescent-indicator dyes. It is based on a targeted pressure ejection of the dye into the tissue of interest and can be used for a large spectrum of indicator dyes, including Oregon Green 488 BAPTA-1 acetoxymethyl ester and Fura-2 acetoxymethyl ester. Through the use of dye mixtures and multicolor imaging, this technique allows the visualization of distinct neurons and glial cells up to 500 microm below the brain surface. It is suitable for staining the brain tissue of various different species (e.g., mouse, rat, cat and zebrafish) at all developmental stages. When combined with brain microendoscopy, it allows the monitoring of intracellular calcium signals in awake, behaving animals. The total time required to carry out the protocol, including dissection and cell staining, is approximately 2 h. Thereafter, imaging experiments might be performed for at least 6 h.     

Effectiveness of CSE to counterstain particles and dead bacterial cells with permeabilised membranes: application to viability assessment in waters

The CSE dye (Chemunex, Maisons-Alfort, France) was combined with an activity marker to improve bacterial activity assessment in natural waters. Its effectiveness to counterstain dead cells with permeabilised membranes was investigated on live and dead cells of a variety of strains from collections or isolated from the natural environment. Cells were killed by heat treatment. For all strains tested, the fluorescent dye showed an intense staining of killed cells having permeabilised membranes while no significant signal was detected when applied to live cells. Furthermore, the CSE dye had no toxicity on viable cells. Then, CSE was combined with the ChemChrome V6 dye (Chemunex) to assess the activity of bacterial cells in different waters. Both fluorescences were analysed simultaneously by solid-phase cytometry. The active cell counts were sometimes lower when both dyes were combined suggesting that CSE was able to counterstain cells having a residual esterase activity and compromised membranes. These cells were subtracted from the active cell counts determined with ChemChrome V6. In most samples, active cell counts were congruent with those determined by the direct viable count method.     

Bacterial fingerprinting by flow cytometry: bacterial species discrimination.

BACKGROUND: A flow cytometric measurement (FCM) technique has been developed to size DNA fragments. Individual fragments of a restriction digest of genomic DNA, stained with an intercalating dye, are passed through an ultrasensitive cytometer. The measured fluorescence intensity from each fragment is proportional to the fragment length. METHODS: The isolation of bacterial genomic DNA and digestion by restriction enzymes were performed inside an agarose plug. Rare cutting enzymes were employed to produce a manageable number of DNA fragments. Electroelution was used to move the DNA fragments from the agarose plug into a solution containing polyamines to protect the DNA from shear-induced breakage. The DNA was stained with the bisintercalating dye thiazole orange homodimer and introduced into our ultrasensitive flow cytometer. A histogram of the fluorescence intensities (fingerprint) was constructed. RESULTS: Gram-positive Bacillus globigii and gram-negative bacteria Escherichia coli and Erwinia herbicola were distinguished by the fingerprint pattern of restriction fragments of their genomic DNA. DNA sizes determined by FCM are in good agreement with pulsed-field gel electrophoresis (PFGE) analysis. Flow cytometry requires only picogram quantities of purified DNA and takes less than 10 min for data collection and analysis. When the total sample preparation time is included, the analysis times for PFGE and FCM are similar ( approximately 3 days). CONCLUSIONS: FCM is an attractive technique for the identification of bacterial species. It is more sensitive and potentially much faster than PFGE.     

Isolation of functional single cells from environments using a micromanipulator: application to study denitrifying bacteria

We developed a novel method to isolate functionally active single cells from environmental samples and named it the functional single-cell (FSC) isolation method. This method is based on a combination of substrate-responsive direct viable counts, live-cell staining with 5-carboxyfluorescein diacetate acetoxymethyl ester, and micromanipulation followed by cultivation in a medium. To evaluate this method, we applied it to study a denitrifying community in rice paddy soil. Similar denitrifier counts were obtained by the conventional most probable number analysis and our FSC isolation method. Using the FSC isolation method, 37 denitrifying bacteria were isolated, some of which harbored copper-containing nitrite reductase gene (nirK). The 16S rRNA gene analysis showed that members belonging to the genera Azospirillum and Ochrobactrum may be the major denitrifiers in the rice paddy soil. These results indicate that the FSC isolation method is a useful tool to obtain functionally active single cells from environmental samples.     

荧光法快速检测活菌数的方法研究及应用

【背景】Calcein UltraGreen~(TM)AM是一种新型荧光染料,用于标记和监测活细胞。【目的】基于该荧光染料的荧光特性及其在活细胞内的稳定特性,建立一种荧光定量快速检测活细菌总数的方法,并在实际样品中应用校正。【方法】通过应用荧光染料对细菌进行染色,再进行荧光强度检测,同时以平板计数法作平行对照,建立荧光强度值-活菌数标准曲线。【结果】确定了染色细菌的最佳pH值为8.0。该检测方法仅需固定染色温度,染色时间在20-30min范围即可快速检测。建立了革兰氏阴性菌铜绿假单胞菌NY3、大肠杆菌和革兰氏阳性菌芽孢杆菌、红平红球菌FF、金黄色葡萄球菌和枯草芽孢杆菌的细菌总数与相对荧光强度值标准曲线。当菌悬液OD600值在0.01-0.30范围内时,上述6种细菌与荧光信号强度呈良好的线性关系(R20.99)。【结论】当样品菌悬液浓度范围控制在105-109CFU/mL时,建立的荧光检测方法快速便捷,精密度、重复性、稳定性、回收率和准确度均较好,可应用于微生物实验、固体菌剂发酵、食品卫生与安全、环境检测等领域的活细菌总数现场快速检测。     

Determination of Giardia cyst viability in environmental and faecal samples by immunofluorescence, fluorogenic dye staining and differential interference contrast microscopy

Amongst the techniques suggested for the determination of Giardia cyst viability, the use of the fluorogenic dyes, fluorescein diacetate (FDA) and propidium iodide (PI) is the most often recommended, even though it appears to overestimate the number of viable cysts. In the present study, the replacement of FDA with 4',6-diamidino-2-phenylindole (DAPI) allowed simultaneous direct immunofluorescence with monoclonal antibody labelled with fluorescein isothiocyanate (MAb-FITC). Under these conditions, it was possible both to quantify the cysts according to the immunofluorescence technique, and to appreciate their viability by using fluorogenic dye staining (DAPI and PI) and differential interference contrast (DIC) microscopy. This method proved to be significantly better than the counting methods normally suggested. The technique has been applied to Giardia cysts recovered from faeces and wastewater sludge.     

Application of laser scanning for the rapid and automated detection of bacteria in water samples

It is widely accepted that the heterotrophic plate count method may not support the growth of all viable bacteria which may be present within a water sample and that alternative procedures using 'viability markers' may yield additional information. In this study, ChemChrome B (CB), which is converted to a fluorescent product by esterase activity, was used to stain viable bacteria (captured by membrane filtration) from potable water samples. The labelled bacteria from each sample were subsequently enumerated using a novel laser scanning instrument (ChemScan). Analysis of 107 potable water samples using this procedure demonstrated the presence of a significantly greater number of bacteria than were detected by culture (z-test, P < 0.05). The mean number of bacteria isolated by culture on R2A agar incubated at 22 degrees C for 7 d was only 25.2% of the total number of viable bacteria detected using the CB/ChemScan viability assay. Further analysis of 81 water samples using a 5-cyano-2,3,4-tolyl-tetrazolium chloride (CTC) viability assay also demonstrated the presence of many viable bacteria which were not capable of growth under the culture conditions employed in this study. However, the results indicate that ChemChrome B has the ability to stain a significantly greater number of heterotrophs than CTC (z-test, P < 0.05). In contrast, six potable waters were identified in which the CTC viability assay resulted in counts greater than those obtained using CB. The ChemScan instrument was successfully used for rapid and accurate enumeration of labelled micro-organisms, allowing information on the total viable microbial load of a water sample to be determined within 1 h. Furthermore, the ChemScan system has the potential for use in detecting specific organisms labelled with fluorescently-labelled antibodies or nucleic acid probes.     

FLOW CYTOMETRIC APPLICABILITY OF FLUORESCENT VITALITY PROBES ON PHYTOPLANKTON1

The applicability of six fluorescent probes (four esterase probes: acetoxymethyl ester of Calcein [Calcein‐AM], 5‐chloromethylfluorescein diacetate [CMFDA], fluorescein diacetate [FDA], and 2′,7′‐dichlorofluorescein diacetate [H₂DCFDA]; and two membrane probes: bis‐(1,3‐dibutylbarbituric acid) trimethine oxonol [DiBAC₄(3)] and SYTOX‐Green) as vitality stains was tested on live and killed cells of 40 phytoplankton strains in exponential and stationary growth phases, belonging to 12 classes and consisting of four cold‐water, 26 temperate, and four warm‐water species. The combined live/dead ratios of all six probes indicated significant differences between the 12 plankton classes (P < 0.01) and between individual species (P < 0.05). No specific differences were observed among strains of one species, among species or strains from different origin, nor between cells in exponential and stationary growth phase except for FDA. FDA showed a significant (P < 0.05) drop of <20% in fluorescence intensity in stationary cells. Of the four esterase probes, the live/dead ratios of FDA and CMFDA were not significantly different from each other, and both performed better than Calcein‐AM and H₂DCFDA (P < 0.001). Of the two membrane probes, DIBAC₄(3) stained rhodophytes and euglenophytes much better than SYTOX‐Green. The 13 algal strains best stainable (high live/dead ratios) among all six probes belonged to nine genera from six classes of phytoplankton. In conclusion, FDA, CMFDA, DIBAC₄(3), and SYTOX‐Green represent a wide choice of vitality probes in the study of phytoplankton ecology, applicable in many species from different algal classes, originating from different regions and at different stages of growth.     

Studies in gram staining.

Gram-negative bacteria stained with crystal violet are decolorized by 95% alcohol within 2 min, whereas Gram-positive bacteria require at least 3 min treatment. Aqueous solutions of safranin, neutral red, and fuschsin replace crystal violet from stained Gram-positive bacteria more quickly than alcohol alone, and alcoholic solutions of these counterstains are in most cases still more effective. Treatment of crystal violet-stained organisms with alcoholic safranin (0.25%) for 15 sec will distinguish Gram-positive bacteria (violet) from Gram-negative bacteria (pink). Alcohol containing very low concentrations of iodine generally decolorizes crystal violet-stained Gram-positive bacteria more quickly than alcohol alone. Increasing concentrations of iodine in alcohol reduce the rate of decolorization of stained bacteria, but stained Gram-negative bacteria are still readily decolorized. The addition of 0.1% iodine to alcohol increases the rate of extraction of crystal violet by alcohol from Gram-negative organisms, but delays extraction of dye from Gram-positive organisms, and this applies when counterstain is also present. A two-solution modification of Gram staining is described in which crystal violet-stained bacteria are treated with an alcoholic solution of safranin, fuchsin, and iodine.     

Studies in Gram Staining

Gram-negative bacteria stained with crystal violet are decolorized by 95% alcohol within 2 min, whereas Gram-positive bacteria require at least 3 min treatment. Aqueous solutions of safranin, neutral red, and fuchsin replace crystal violet from stained Gram-positive bacteria more quickly than alcohol alone, and alcoholic solutions of these counterstains are in most cases still more effective. Treatment of crystal viokt-stained organisms with alcoholic safranin (0.25%) for 15 scc will distinguish Gram-positive bacteria (viokt) from Gram-negative bacteria (pink).

Alcohol containing very low concentrations of iodine generally decolorizes crystal violet-stained Gram-positive bacteria more quickly than alcohol alone. Increasing concentrations of iodine in alcohol reduce the rate of decolorization of stained bacteria, but stained Gram-negative bacteria are still readily dccolorized. The addition of 0.1% iodine to alcohol increases the rate of extraction of crystal violet by alcohol from Gram-negative organisms, but delays extraction of dye from Gram-positive organisms, and this applies when counterstain is also present. A two-solution modification of Gram staining is described in which crystal violet-stained bacteria are treated with an alcoholic solution of safranin, fuchsin, and iodine.     

Rapid monitoring of microbial contamination on herbal medicines by fluorescent staining method

AIMS: To apply fluorescent staining method for fast assessment of microbial quality of herbal medicines. METHODS AND RESULTS: The number of total bacteria and esterase-active bacteria on powdered traditional Chinese medicines were enumerated by fluorescent staining method using 6-carboxyfluorescein diacetate (6CFDA) and 4',6-diamidino-2-phenylindole (DAPI), and they were compared with colony-forming units (CFU). The CFU was approximately 10(3) per gram in ginseng radix, and no bacterial colonies were detected from others. However, the total bacterial number (TDC) was more than 10(7) per gram, and number of bacteria possessing esterase activity ranged from 1 to 3% of TDC. CONCLUSIONS, SIGNIFICANCE AND IMPACT OF THE STUDY: Many bacteria in each Chinese medicine had enzyme activity and most of them could not be detected by conventional plate counting technique. Enumeration of bacterial cells on traditional Chinese medicines by fluorescent staining method requires less than 1 h. The double staining method with 6CFDA and DAPI could be applicable to rapid microbial monitoring of crude drugs.     

The Use of Fluorescein Diacetate and Ethidium Bromide as a Viability Stain for Isolated Islets of Langerhans

There is a need for a simple, rapid, sensitive method for assessing the viability of isolated islets of Langerhans. In this study the fluorescent dyes fluorescein diacetate (FDA) and ethidium bromide (EB) have been used to provide a viability assay for isolated rat islets. Discrimination of living from dead islets is efficient; in a blind sorting experiment using freshly isolated islets and islets killed by either heat or alcohol, viability determined by insulin secretion in response to glucose stimulation correlated well with viability as determined by FDA/EB staining. Furthermore, it is possible to discriminate degrees of viability, and a scoring system is described for this purpose which is shown to correlate with another index of viability, the ATF content A reliable viability stain should not itself be toxic; FDA/EB stained islets remain viable after staining, showing normal response to glucose stimulation and normal function after transplantation.     

水稻原生质体细胞核及原生质体融合体的简易染色观察法

筛选出一种荧光染料罗丹明B(Rhodamine B),利用该荧光染料染色,原生质体细胞核在普通光学显微镜或荧光显微镜下呈红色或发出强烈的桔红色荧光,能清晰地进行分辨。利用罗丹明B或者使用荧光染料FDA,对两种不同来源的原生质体进行染色,在荧光显微镜下,两种不同来源的原生质体分别发出桔红色或绿色荧光,因此可以用于原生质体融合中不同的融合体类型的观察和分析。     

Determination of orchid seed viability using fluorescein diacetate

Abstract Fluorescein diacetate (FDA) staining (0.25% FDA for 10 min) was found to be a suitable technique for the rapid determination of orchid seed viability. Penetration of the dye through the testa varies between species, thus the test is ideally performed on isolated embryos. Direct FDA application to isolated embryos of seeds taken from dry storage, but after the surface had been sterilized, elicits a poor staining reaction. Incubation of the surface sterilized seeds in distilled water for 16 h, either at 6°C or at room temperature, prior to applying the test was found to overcome this problem. In the range of species studied, FDA staining accurately indicates seed viability when compared with germination of seeds on sterile nutrient media. Storage of dry Dactylorhiza fuchsii (Druce) Soó seed at an elevated temperature of 62°C indicated that, under such conditions of accelerated ageing, the FDA test accurately describes the rate of seed viability loss.     

Relationship between fluorescein diacetate-stained hyphae and oxygen utilization, glucose utilization, and biomass of submerged fungal batch cultures.

The relationship between fungal activity and staining with fluorescein diacetate (FDA) was investigated by growing Penicillium citrinum and Rhizoctonia solani in submerged batch cultures at different initial glucose concentrations and aeration rates. A modified FDA staining method, similar to the Jones and Mollison technique (P. Jones and J. Mollison, J. Gen. Microbiol. 2:54-69, 1948), was developed to assess both total and FDA-stained hyphae. In previous studies, soil hyphae stained with FDA were considered viable. However, determination of a quantitative relationship between FDA staining and fungal activity is necessary before such an assumption can be made. Growth rates and the rate of change in the percentage of FDA-stained hyphae were significantly correlated. The regression equation calculated for the relationship was: growth rate (mg . ml-1 . h-1) = 0.34 + 1.1 (rate of change in the percentage of FDA-stained hyphae [. ml-1 . h-1]). Changes in activity as measured by O2 utilization, glucose utilization, and biomass correlated significantly with changes in the percentage of FDA-stained hyphae, although the relationships among these parameters were different for each fungal species. Fungal growth stage was also correlated with the percentage of FDA-stained hyphae. Staining was 10% or greater during fungal growth and less than 10% during the late growth, stationary, and death phases. Thus, the rate of change in the percentage of FDA-stained hyphae can be used to predict fungal activity rate changes for single fungal cultures and growth rates for mixed fungal cultures, and the growth stage can be assessed by the percentage of FDA-stained hyphae.     

Solid phase cytometry as a tool to detect viable but non-culturable cells of Campylobacter jejuni

Solid phase cytometry (SPC) in conjunction with fluorescent viability staining has been investigated as a tool to detect viable but non-culturable Campylobacter jejuni in drinking water. Inoculated water samples were filtered over a polyester membrane filter and the retained cells were stained using a carboxyfluorescein ester as a substrate for intracellular esterases. The number of green fluorescent bacteria was automatically counted by an Ar laser scanning device (ChemScan) in 3 min. In parallel, the plate count was determined on Columbia Blood Agar. The number of culturable cells decreased below the detection limit of plate counting in less than 50 days. In contrast, the number of fluorescent bacteria remained at its initial level for at least 85 days. The discrepancy between the two results can be attributed to the transition of culturable C. jejuni cells into VBNC C. jejuni cells. Furthermore, as SPC can distinguish between low numbers of dividing and non-dividing cells of Campylobacter it has the potential to monitor attempts to resuscitate VBNC cells.     

The use of fluorescein diacetate and ethidium bromide as a viability stain for isolated islets of Langerhans

There is a need for a simple, rapid, sensitive method for assessing the viability of isolated islets of Langerhans. In this study the fluorescent dyes fluorescein diacetate (FDA) and ethidium bromide (EB) have been used to provide a viability assay for isolated rat islets. Discrimination of living from dead islets is efficient; in a blind sorting experiment using freshly isolated islets and islets killed by either heat or alcohol, viability determined by insulin secretion in response to glucose stimulation correlated well with viability as determined by FDA/EB staining. Furthermore, it is possible to discriminate degrees of viability, and a scoring system is described for this purpose which is shown to correlate with another index of viability, the ATP content. A reliable viability stain should not itself be toxic; FDA/EB stained islets remain viable after staining, showing normal response to glucose stimulation and normal function after transplantation.