Automatic cell identification and enrichment in lung cancer: V. Adenocarcinoma and large cell undifferentiated carcinoma

The aims of this study were to develop a protocol for the identification and enrichment of cancer cells from sputum obtained from patients with adenocarcinoma of the lung (n = 6) and large-cell undifferentiated carcinoma of the lung (n = 2), and to compare these findings with the results from our previous studies on other cell types from lung cancer. The hypotheses tested were: Cancer cells in sputum can be preserved following flow sorting. Enrichment for cancer cells from acridine orange (AO)-stained specimens can be achieved. Discrimination of cancer cells from noncancer cells is by AO green fluorescence and discrimination of lymphocytes from other cell types is by AO red fluorescence. Cancer cells are consistently enriched in the AO high green and red fluorescence region, although, for a given cell type, maximal enrichment is patient-dependent. Finally, cancer cell enrichment and lymphocyte exclusion can be done simultaneously. Cells from sputum were initially fixed, stained with AO, sorted on a dual parameter flow sorter, and classified into six groups corresponding to two ranges of green and three ranges of red fluorescence intensities. Cells of each region were stained by the method of Papanicolaou and differential counts were performed to determine the relative frequencies (i.e., purities) of leukocytes, macrophages, squamous cells, and cancer cells, in sorted and unsorted (i.e., control) samples. The average purity of leukocytes (81%), macrophages (6%), squamous cells (11%), and cancer cells (2%) varied markedly from sample to sample. However, the largest enrichment values (i.e., ratio of purity of a cell type in a sorted sample to its purity in the unsorted control sample) achieved for cancer cells consistently occurred for each patient sample in the region corresponding to high green and high red fluorescence intensities. Experimentally, a cancer cell average enrichment of sixteen-fold was obtained by this method. Additionally, fluorescence intensity ranges which increased the enrichment for macrophages by cell sorting typically excluded leukocytes and squamous cells, and vice versa. Finally, red fluorescence intensity was the primary discriminatory parameter for all cell types studied, although the additional use of green fluorescence intensity significantly increased cancer cell enrichment rates.(ABSTRACT TRUNCATED AT 400 WORDS)     

Analysis of Plasmodium falciparum growth in culture using acridine orange and flow cytometry

The growth of Plasmodium falciparum in cultures of human red blood cells was studied using acridine orange to stain RNA and DNA, followed by flow cytometric analysis. The cycle of the parasite is characterized by a period of growth, prior to initiation of DNA synthesis, in which a significant increase in red fluorescence is observed, with only a small change in green fluorescence. Following this phase, which is formally similar to the G1 period in mammalian cells, initiation of DNA synthesis is characterized by increases in green fluorescence. Sorting of cells from several regions of the two-dimensional display shows that the distribution of morphological stages correlates with differences in red and green fluorescence. The effect of aphidicolin on the growth cycle of the parasite was also studied.     

Photoprotective implications of leaf variegation in E. dens-canis L. and P. officinalis L

Variegated leaves occur rarely in nature, but there are some species, primarily in the forest understory, that possess this characteristic. We recently studied two variegated plants: Erytronium dens-canis L., which is characterised by a pattern of red patches and Pulmonaria officinalis L., with light green spots. These non-green areas could attenuate light reaching mesophyll cells with respect to green sections. The aim of the study was to verify whether such red and light green parts are more photoprotected than green ones and if this trait could be of adaptive value. Red patches in E. dens-canis were due to a single layer of red cells in the upper parenchyma, which accumulated anthocyanins. Light green spots in P. officinalis were caused by the presence of loosely arranged cells instead of a well-established layer of packed cells in the palisade parenchyma. Chlorophyll fluorescence imaging was performed under light treatment, showing a greater decrease of photochemical efficiency in red and light green patches than in green sections. Differences in the extent of photochemical efficiency among patches were not attributable to different activation of the xanthophyll cycle. These observations failed to confirm our initial hypothesis, but they questioned the physiological reason for this higher sensitivity in red and light green patches of photosynthetic tissues. Chlorophyll fluorescence imaging was therefore performed in the field. The same pattern of photochemical efficiency was maintained only in E. dens-canis. The current results demonstrate that in both species the benefits of variegation, if any, are different from enhanced photosynthetic performance.     

Automatic cell identification and enrichment in lung cancer. I. Light scatter and fluorescence parameters.

Two physical parameters were investigated to automatically recognize cells in sputum from human squamous cell carcinoma of the lung and to separate them for preparation by the Papanicolaou methods, for human interactive identification and for automated high resolution image analysis. The two parameters, 0.5-15.0 degrees forward argon-ion laser light scatter to estimate total cell size and 546 nm Acridine orange fluorescence to approximate total cell DNA content, were measured in a flow-through fluorescence activated cell sorting system. Enrichment for neoplastic cells in three cases of squamous cell carcinoma of the lung averaged 7.8-fold over the original sputum when only green fluorescence was used and 10.5-fold using green fluorescence and forward light scatter. The average enrichment for neoplastic cells was 65.6-fold relative to polymorphonuclear deenrichment.     

Automatic cell identification and enrichment in lung cancer. II. Acridine orange for cell sorting of sputum.

Fluorescence spectra were obtained from cells from sputum and pleural effusions stained with different fluorescent dyes and fixed by alternate methods. The spectra were referenced to a standard allowing for fluorescence comparisons of unstained and stained cells under various conditions. The metachromasia of acridine orange-stained cells offers nuclear/cytoplasmic differentiation in a single stain; mithramycin and propidium iodide do not. Unstained cells have an appreciable amount of green (546 nm) fluorescence, as does Carbowax in Saccomanno's preservative. Cytoplasm stained with acidine orange also has appreciable green fluorescence. Consequently, cells with much cytoplasm have high total fluorescence. Cytoplasmic fluorescence is negligible with mithramycin or propidium iodide. The metachromasia of acridine orange-stained cells is altered by alcohol and Carbowax levels in fixatives, keeping other factors constant.     

利用荧光蛋白标记西瓜枯萎病菌的过氧化物酶体及细胞核

西瓜枯萎病是一种世界范围的西瓜毁灭性病害,其病原菌为尖孢镰刀菌西瓜专化型(Fusarium oxysporum f.sp.niveum,FON)。研究病原菌生长发育和侵染的机制是解决病害的根本途径。利用荧光蛋白对细胞或细胞器进行标记,是病原菌研究中的重要方法。该研究利用绿色荧光蛋白和红色荧光蛋白对FON的细胞核和过氧化物酶体进行了荧光标记。通过农杆菌介导转化(Agrobacterium tumefaciens-mediated transformation,AtMT),该文将3种不同的荧光定位载体分别导入FON,获得了细胞核红色荧光标记的转化子(潮霉素抗性,含mCherry-H2B融合蛋白),以及过氧化物酶体绿色(潮霉素抗性,含GFP-PTS1融合蛋白)和红色(潮霉素抗性,含DsRED-PTS1融合蛋白)荧光标记的转化子各1种。在标记细胞核的菌株中,菌丝、孢子都可见明亮、圆形的红色荧光点,荧光点与DAPI染色标记的细胞核区域完全重合。在过氧化物酶体标记的菌株中,菌丝、孢子中可见明亮的红色或绿色荧光成小点状分布,符合过氧化物酶体的分布特征,而且在脂类物质诱导的条件下,荧光点的数量明显增加。此外,该文还利用细胞壁荧光染色剂卡氏白对3种荧光蛋白标记菌株进行染色。结果显示,卡氏白染色产生的蓝色荧光与红、绿荧光蛋白的荧光在FON中互不干扰。转化子继代培养和初步分析表明,其表型与野生型无差异,菌株继代后荧光表达稳定、定位明显。该结果为进一步研究FON细胞器动态、生长发育与致病分子机制提供了方法和工具。     

Characterization of the laser-induced blue, green and red fluorescence signatures of leaves of wheat and soybean grown under different irradiance

The blue, green and red fluorescence emission of green wheat ( Triticum aestivum L. var. Rector) and soybean leaves ( Glycine max L. var. Maple Arrow) as induced by UV light (nitrogen laser: 337 nm) was determined in a phytochamber and in plants grown in the field. The fluorescence emission spectra show a blue maximum near 450 nm, a green shoulder near 530 nm and the two red chlorophyll fluorescence maxima near 690 and 735 nm. The ratio of blue to red fluorescence, F450/F690, exhibited a clear correlation to the irradiance applied during the growth of the plants. In contrast, the chlorophyll fluorescence ratio, F690/F735, and the ratio of blue to green fluorescence, F450/F530, seem not to be or are only slightly influenced by the irradiance applied during plant growth. The blue fluorescence F450 only slightly decreased, whereas the red chlorophyll fluorescence decreased with increasing irradiance applied during growth of the plants. This, in turn, resulted in greatly increased values of the ratio, F450/F690, from 0.5 – 1.5 to 6.4 – 8.0. The decrease in the chlorophyll fluorescence with increasing irradiance seems to be caused by the accumulation of UV light absorbing substances in the epidermal layer which considerably reduces the UV laser light which passes through the epidermis and excites the chlorophyll fluorescence of the chloroplasts in the subepidermal mesophyll cells.     

Hematoporphyrin/DAPI staining: simplified simultaneous one-step staining of DNA and cell protein and trial application in automated cytological screening by flow cytometry

We describe a procedure for simplified, simultaneous one-step staining in 10 min for DNA and cell and tissue proteins using a newly developed staining solution containing 0.03% hematoporphyrin (HP) with 0.001% DAPI [or with Hoeschst 33342 (HO)]. These HP/DAPI or HP/HO solutions were especially developed to facilitate a trial of automated cancer cell screening on sputum samples using flow cytometry. Under UV light (365 nm) with fluorescence microscopy, HP/DAPI-stained cells showed red fluorescence (max. 670 nm) of cytoplasm and simultaneous blue fluorescence (max. 470 nm) of nuclei. The distance between the maximum peak of fluorescence spectra of DNA and that of protein was as large as 200 nm, and there was no detectable overlapping of each spectrum at the photometric filter range, which provided accurate measurement of DNA and protein. On flow cytometry, a single UV beam (370 nm) from the argon laser was used for excitation of both dyes. Measurement of DNA was done using a 470-nm bandpass filter and of protein using a 640-nm longpass (or 670-nm bandpass) filter. Reflecting the undetectable overlapping of the fluorescence spectra of protein and DNA, normal diploid cells in sputum revealed horizontal distributions along the 2C level on the dot-plot display of flow cytometry, which made sorting of abnormal hyperdiploid cells and cancer cells easier.     

Fluorescence kinetics in HeLa cells after treatment with cell cycle arrest inducers visualized with Fucci (fluorescent ubiquitination-based cell cycle indicator)

Fucci (fluorescent ubiquitination-based cell cycle indicator) is able to visualize dynamics of cell cycle progression in live cells; G1- and S-/G2-/M-phase cells expressing Fucci emit red and green fluorescence, respectively. This system could be applied to cell kinetic analysis of tumour cells in the field of cancer therapy; however, it is still unclear how fluorescence kinetics change after various treatments, including exposure to anticancer agents. To explore this, we arrested live HeLa cells expressing the Fucci probes at various cell cycle stages and observed the fluorescence, in conjunction with flow cytometric analysis. X-irradiation, HU (hydroxyurea) and nocodazole arrest cells at G2/M boundary, early S-phase and early M-phase, respectively. Although X-irradiation and HU treatment induced similar accumulation kinetics of green fluorescent cells, nocodazole treatment induced an abnormal red fluorescence at M phase, followed by accumulation of both red and green fluorescent cells with 4N DNA content. We conclude that certain agents that disrupt normal cell cycle regulation could cause unexpected fluorescence kinetics in the Fucci system.     

A comparative study of spermatozoal chromatin using acridine orange staining and flow cytometry

Spermatozoa obtained from fish (Clarias gariepinus), human (Homo sapiens), turkeys (Meleagris gallapova), rats (Rattus norvegicus), hamsters (Mesocricetus auratus), and monkeys (Macaca fascicularis) were stained with acridine orange before measuring fluorescence by flow cytometry. These mature sperm from various species produced different intensities of fluorescence while displaying similar ratios of red/green fluorescence. Comparison of the green fluorescence values for the various species showed the sequence (descending order of fluorescence values) human, turkey, monkey, hamster, rat and fish. The DNA complement (as base pairs in the haploid genome) of the various species did not increase in direct proportion to the fluorescence values. This suggests that the DNA was not equally accessible to the dye in the different species tested. The similarity in ratios of red/green fluorescence suggests that the structure of DNA in the chromatin is similar in the different species but abnormal 'satellite' populations of cells that show higher red/green fluorescence ratios than the parent population have been found in sperm samples from monkeys and from some infertile men. Their high red fluorescence intensities were not caused by RNA because treatment with RNAse did not alter the red fluorescence. It is possible that these cells contain larger amounts of denatured (single stranded) DNA.     

Increase in acridine orange (AO) fluorescence intensity of monocytes cultured in plastic tissue culture plates as measured by flow cytometry.

Although the green-red fluorescence of AO is an accepted measure of DNA-RNA content, respectively, it is actually a measure of the fluorescence of dye bound to nucleic acids, and may vary with changes in accessibility to the dye. It has been shown for example that extraction of nuclear proteins results in a marked increase in DNA stainability. Moreover, in certain cell systems the binding of fluorochromes correlates with structural modifications in chromatin that accompany cell differentiation. We report here that changes in green & red fluorescence intensity also occur in long-term monocyte cultures. The increased red fluorescence intensity observed in cultured monocytes may reflect ribosomal RNA synthesis and the increased green fluorescence enhanced AO accessibility to DNA due to changes in chromatin organization. We compared cultured monocytes from bladder cancer patients and healthy donors. The results indicate a small but statistically significantly greater increase in mean green & red fluorescence of cultured monocytes from the cancer patients. These fluorescence variations may indicate differences in the immunologic status of cancer patients and/or be related to disease state.     

Two-color flow-cytometric analysis of the growth cycle of Plasmodium falciparum in vitro: identification of cell cycle compartments

A previous study (Hare JD, Bahler DW: J Histochem Cytochem 34:215, 1986) has shown that the flow cytometric analysis of acridine-orange-stained Plasmodium falciparum growing in vitro generates a complex two-color display, regions of which correlate with the major morphological stages. In this report, four cell cycle compartments (A-D) are defined by characteristic ratios of red and green fluorescence of cells distributed throughout the erythrocytic cycle as well as by the differential effects of several metabolic inhibitors. The primary characteristic of cells in compartment A is the significant increase in red fluorescence. Inhibition of DNA synthesis by either aphidicolin or hydroxyurea causes the accumulation of cells at the interface between compartments A and B, whereas n-butyrate prevents cells in compartment A from reaching the A-B interface. Cells in compartment A display a small increase in green fluorescence which is independent of DNA synthesis but is enhanced by n-butyrate treatment. Cells in compartment B display a continued increase in red fluorescence coupled with a significant increase in green fluorescence, reflecting the onset of DNA synthesis in compartment B. The transition to compartment C is more abrupt and is associated with a marked increase in green fluorescence and little increase in red fluorescence. Compartment D is characterized by an increase in red fluorescence and a continued rise in green fluorescence. It is postulated that these discontinuities in the two-color display reflect not only changes in the rates of RNA and DNA synthesis but also decondensation of parasite chromatin in compartment A as the organism prepares for DNA synthesis, and re-condensation in compartment D as the newly replicated chromatin prepares for segregation into merozoites. The method described promises to provide a sensitive and rapid technique to study the effects of various factors on the growth cycle of the parasite.     

A quantitative method for evaluating bivariate flow cytometric data obtained using monoclonal antibodies to bromodeoxyuridine.

A method is presented for analyzing data from bivariate analysis of cell populations exposed to bromodeoxyuridine and subsequently examined both for the presence of BrdUrd and for the cellular DNA content. It is shown that certain features may be defined in the bivariate data which are constant independent both of cell type and, within limits, experimental variability. These landmark features include the ratio of red, DNA, fluorescence of G2 + M cells to G1 cells, the ratio of green fluorescence corresponding to the non-specific binding of unlabeled G2 + M cells to unlabeled G1 cells, and the distribution of green fluorescence in unlabeled cells. The landmarks make it possible to standardize rules for establishing the separation line between-labeled and unlabeled cells as required in these experiments to obtain estimates of cytokinetic parameters. Values obtained for the DNA synthesis time and the potential doubling time which result from different decision rules for distinguishing labeled from unlabeled are compared in two murine tumor lines. The potential doubling time, but not the DNA synthesis time is shown to depend sensitively on the separation line. Suggestions are presented for analyzing clinical data with this procedure.     

Dynamic characteristics of the fluorescence of human peripheral blood neutrophilic polymorphonuclear leukocytes and lymphocytes intravitally fluorochrome-stained with acridine orange]

Neutrophil segmentonuclear leukocytes and lymphocytes of the human peripheral blood vitally stained with Acridine Orange (AO) in concentrations of 250 and 330 mcg/ml show different fluorescence dynamics. The number of neutrophil segmentonuclear granulocytes with green fluorescence of nuclei decreases, whereas the number of cells with red fluorescence of nuclei increases. As a criterion of this process, time T1/2 is taken during which the number of green-fluorescent cells decreases twofold. With AO concentrations of 250 and 330 mcg/ml, T1/2 is equal to 40 or 5 minutes, resp. The nuclei of lymphocytes within a 60 minutes observation show green fluorescence. This effect is likely to be due to structural-functional peculiarities of neutrophil segmentonuclear granulocytes and lymphocytes.     

Profiles of photosynthesis within red and green leaves of Quintinia serrata

We have measured photosynthesis at the cellular, tissue, and whole leaf levels to understand the role of anthocyanin pigments on patterns of light utilization. Profiles of chlorophyll fluorescence through sections of red and green leaves of Quintinia serrata showed that anthocyanins in the mesophyll restricted absorption of green light to the uppermost palisade mesophyll. The distribution was further restricted when anthocyanins were also present in the upper epidermis. Mesophyll cells located beneath a cyanic light-filter assumed the characteristic photosynthetic features of shade-adapted cells. As a result, red leaves showed a 23% reduction in CO₂ assimilation under light-saturating conditions, and a lower threshold irradiance for light-saturation, relative to those of green leaves. The photosynthetic characteristics of red leaves are comparable to those of shade-acclimated plants.     

Discrimination of depolarized from polarized mitochondria by confocal fluorescence resonance energy transfer

Mitochondrial depolarization promotes apoptotic and necrotic cell death and possibly other cellular events. Polarized mitochondria take up cationic tetramethylrhodamine methylester (TMRM), which is released after depolarization. Thus, TMRM does not label depolarized mitochondria. To identify both polarized and depolarized mitochondria in living cells, cultured rat hepatocytes, and sinusoidal endothelial cells were co-loaded with green-fluorescing MitoTracker Green FM (MTG) and red-fluorescing TMRM for imaging by laser scanning confocal microscopy. Like TMRM, MTG is a cationic fluorophore that accumulates electrophoretically into polarized mitochondria. Unlike TMRM, MTG binds covalently to intramitochondrial protein thiols and remains bound after depolarization. In cells labeled only with MTG, excitation with blue (488 nm) light yielded green but almost no red fluorescence. After subsequent loading with TMRM, green MTG fluorescence became quenched. Instead, blue excitation yielded red fluorescence. Mitochondrial de-energization restored green fluorescence and abolished red fluorescence. Conversely, when MTG was added to TMRM-labeled cells, red fluorescence excited by blue light was enhanced, an effect again reversed by de-energization. These observations of reversible quenching of donor fluorescence and augmentation of acceptor fluorescence signify fluorescence resonance energy transfer (FRET). In undisturbed hepatocytes, spontaneous depolarization of a subfraction of mitochondria was an ongoing phenomenon. In conclusion, confocal FRET discriminates individual depolarized mitochondria against a background of hundreds of polarized mitochondria.     

Monitoring promoter activity in a single bacterial cell by using green and red fluorescent proteins

We investigated the possibility of monitoring promoter activity with flow cytometry by using green fluorescent protein (GFPmut2) and red fluorescent protein (drFP583) in a single bacterial cell. The drFP583 was used as an intrinsic marker of the bacterial cells, because it was expressed constantly in Escherichia coli MC1061 strain. The GFPmut2 expressed under the control of the Hg(2+) ion inducible mer promoter/operator, was used to study promoter activity. Over 75% of the cells were positive for red and green fluorescence in flow cytometric analysis. The average green fluorescence of the whole population increased from 6.7 to 1700 when the mercury concentration was increased from 0 to 1 x 10(-4) M, while the red fluorescence was unaffected by the mercury concentration. These results show that gfpmut2 and drFP583 could be expressed under different promoters in one bacterial cell and measured independently with a flow cytometer.     

Radiosensitivity of early and late M-phase HeLa cells isolated by a combination of fluorescent ubiquitination-based cell cycle indicator (Fucci) and mitotic shake-off

The mitotic shake-off method revealed the remarkable variation of radiosensitivity of HeLa cells during the cell cycle: M phase shows the greatest radiosensitivity and late S phase the greatest radioresistance. This method harvests all M-phase cells with a round shape, making it impossible to further subdivide M-phase cells. Recently, the fluorescent ubiquitination-based cell cycle indicator (Fucci) was developed; this system basically causes cells in G(1) to emit red fluorescence and other cells to emit green fluorescence. Because the green fluorescence rapidly disappears at late M phase, two-dimensional flow cytometry analysis can usually detect a green(high)/red(low) fraction including S-, G(2)- and early M-phase cells but not a transitional fraction between green(high)/red(low) and green(low)/red(low) including late M-phase cells. However, combining the shake-off method concentrated the transitional fraction, which enabled us to separate early and late M-phase cells without using any drugs. Here we demonstrate for the first time that cells in early M phase are more radiosensitive than those in late M phase, implying that early M phase is the most radiosensitive sub-phase during the cell cycle.