Clinical applications of laser scanning cytometry

This study reviews existing and potential clinical applications of laser scanning cytometry (LSC) and outlines possible future developments. LSC provides a technology for solid phase cytometry. Fluorochrome-labeled specimens are immobilized on microscopic slides that are placed on a conventional epifluorescence microscope and analyzed by one or two lasers. Data comparable to flow cytometry are generated. In addition, the position of each event is recorded, a feature that allows relocalization and visualization of each measured event. The major advantage of LSC compared with other cytometric methods is the combination of two features: (a) the minimal clinical sample volume needed and (b) the connection of fluorescence data and morphological information for the measured event. Since the introduction of LSC, numerous methods have been established for the analysis of cells, cellular compartments, and tissues. Although most cytometric methods use only two or three colors, the characterization of specimens with up to five fluorochromes is possible. Most clinical applications have been designed to determine ploidy and immunophenotype; other applications include analyses of tissue biopsies and sections, fluorescence in situ hybridization, and the combination of vital and nonvital information on a single-cell basis. With the currently available assays, LSC has proven its wide spectrum of clinical applicability in slide-based cytometry and can be introduced as a standard technology in multiple clinical settings.     

Multiparameter analysis of human epithelial tumor cell lines by laser scanning cytometry

Laser scanning cytometry (LSC) is a relatively new slide-based technology developed for commercial use by CompuCyte (Cambridge, MA) for performing multiple fluorescence measurements on individual cells. Because techniques developed for performing four or more measurements on individual lymphoid cells based on light scatter as a triggering parameter for cell identification are not suitable for the identification of fixed epithelial tumor cells, an alternative approach is required for the analysis of such cells by LSC. Methods for sample preparation, event triggering, and the performance of multiple LSC measurements on disaggregated fixed human cells were developed using normal lymphocytes and two human breast cancer cell lines, JC-1939 and MCF-7, as test populations. Optimal conditions for individual cell identification by LSC were found to depend on several factors, including deposited cell density (cells per unit area), the dynamic range of probe fluorescence intensities, and intracellular distribution of the fluorescent probe. Sparsely deposited cells exhibited the least cell overlap and the brightest immunofluorescent staining. Major advantages of using DNA probes over a cytoplasmic immunofluorescent protein marker such as tubulin for event triggering are that the former exhibit greater fluorescence intensity within a relatively sharply demarcated nuclear region. The DNA-binding dye LDS-751 was found to be suboptimal for quantitative DNA measurements but useful as a triggering measurement that permits the performance of simultaneous fluorescein isothiocyanate-, phycoerythrin-, and indodicarbocyanine-based measurements on each cell. A major potential advantage of LSC over flow cytometry is the high yields of analyzable cells by LSC, permitting the performance of multiple panels of multicolor measurements on each tumor. In conclusion, we have developed and optimized a technique for performing multiple fluorescence measurements on fixed epithelial cells by LSC based on event triggering using the DNA-binding dye LDS 751. Although not ideal for quantitative measurements of cell DNA content, the large Stokes shift of this dye permits the performance of three or more additional fluorescence measurements on each cell.     

Laser scanning cytometry can complement the flow cytometric DNA analysis in paraffin-embedded cancer samples: a paradigmatic case

Archival studies on paraffin-embedded tumor samples are often complicated by difficulty obtaining a reliable diploid DNA standard. Nontumor cells, e.g., inflammatory and stromal cells, most often found interspersed among tumor cells, would represent a solution to this problem. Unfortunately, there is an inherent difficulty to positively identifying tumor cells in paraffin-embedded specimens. Using an aneuploid paraffin-embedded breast cancer sample, we show here that laser scanning cytometer (LSC) in conjunction with flow cytometry can help to address this issue. Following standard protocols, the tissue was deparaffinized and rehydrated, and the nuclei mechanically isolated before being exposed to propidium iodide. An aliquot served for single-parameter flow cytometric analysis, and the remaining cells were cytocentrifuged onto a microscope slide and LSC analysis was performed. The DNA histogram profiles generated by the two approaches were comparable and both showed the presence of cell populations with different DNA content. To assess the nature of these subsets, we performed a correlated measurement of DNA content and chromatin organization at the single-cell level by LSC. This allowed the identification of several subsets of nuclei. Slides were then stained with Giemsa and the nature of these subsets was assessed morphologically by exploiting the relocating capability of LSC. Inflammatory and stromal cells, residual diploid epithelial cells, and hyperdiploid tumor cells-each characterized by a peculiar coordinate pattern of DNA content and chromatin organization-could be positively identified. Diploid, nontumor cells can then be used as an internal standard for DNA ploidy.     

Determination of ploidy and steroid receptor status in breast cancer by laser scanning cytometry

BACKGROUND: Measurements on DNA content and steroid receptor status in breast cancer are of great clinical interest. Objective determination of estrogen and progesterone receptor expression should help to define the lowest levels of positivity still responding to adjuvant antihormonal therapy. For this purpose, a simple protocol for laser scanning cytometry is presented. METHODS: Analysis of 54 routine breast cancer samples was performed by laser scanning cytometry (LSC). To obtain single cell preparations from fresh tumor tissue, slides were prepared using the Cervisoft cytological device. Exact determination of tumor cell DNA content was done by referring to the CD45-positive tissue leukocyte fraction as the internal diploid reference cell population. Steroid receptor-expressing cells were detected by indirect immunolabeling. RESULTS: Indirect immunofluorescence allowed the best quantification of both the estrogen and progesterone receptor-expressing cell fractions by LSC. The number of receptor-expressing cells could be given in percentage. For comparison, the 10% cutoff value was used to determine receptor positivity. CONCLUSION: LSC enabled a simple, reliable, and inexpensive determination of DNA index and steroid receptor expression in breast cancer specimens by objective criteria.     

Analysis of apoptosis by laser scanning cytometry

Flow cytometry techniques that are widely used in studies of cell death, and particularly in the identification of apoptotic cells, generally rely on the measurement of a single characteristic biochemical or molecular attribute. These methods fail to recognize cell death lacking that attribute, as in some examples of atypical apoptosis. Since apoptosis was originally defined by morphologic criteria, we suggest that for any new cell system the cytometry-defined apoptosis be confirmed by morphologic examination. This quality assurance measure is now provided by laser scanning cytometry (LSC). LSC measurements of cell fluorescence are precise and highly sensitive, comparable to flow cytometry (FCM), and can be carried out on cells on slides, permitting cell by cell correlation of fluorescence cytometry with visual microscopic morphology. In this report we describe adaptations of various flow cytometry techniques for detection of apoptosis by laser scanning cytometry. We also describe features unique to LSC that are useful in recognizing apoptosis. Hyperchromicity of DNA, reflecting chromatin condensation, is evidenced by high maximal pixel values for fluorescence of the DNA-bound fluorochrome. Mitochondrial probes that have been adapted to LSC to measure the drop in mitochondrial transmembrane potential that occurs early in apoptosis include rhodamine 123, 3,3'-dihexiloxadicarbocyanine [DiOC6(3)], and the aggregate dye 5,5',6,6'tetrachloro-1,1',3,3'-tetraethylbenzimidazolcarbocyanine iodide (JC-1). The changes in plasma membrane phospholipids and transport function, also early in apoptosis, are probed by a combination of the fluoresceinated annexin V and DNA fluorochromes such as propidium or 7-aminoactinomycin D. We also review methods of detection of apoptosis based on analysis of DNA fragmentation and their application to clinical oncology. Visual examination of the presumed apoptotic cells detected by cytometry makes it possible to discriminate those that are genuine from monocytes/macrophages that have ingested nuclear fragments via apoptotic bodies. Applications of flow cytometry and laser scanning cytometry in analysis of cell death are discussed and their respective advantages and disadvantages compared.     

DNA ploidy analysis of urinary tract epithelial tumors by laser scanning cytometry

OBJECTIVE: To evaluate a rapid and simple method for DNA content analysis of urinary tract epithelial tumors with laser scanning cytometry (LSC). STUDY DESIGN: The subjects were 25 patients (37 specimens) who underwent surgery for urinary tract epithelial tumors. Tissue specimens of such tumors were frozen immediately after tumor resection and stored at -80 degrees C until used. Touch preparations were made and fixed in ethanol at room temperature. The cell nucleus was stained with propidium iodide solution containing RNase, and DNA ploidy was analyzed by LSC. Nuclear debris and overlapping nuclei were gated out by special statistical filters. In LSC, a normal diploid reference peak was determined by observing lymphocytes morphologically on the computer display of the instrument and/or under the microscope. RESULTS: DNA ploidy could be evaluated in all tumor tissues. The time it took from preparing the tumor specimen to the last measurement was about 40 minutes at the shortest, and measurement of all the specimens was completed within one hour. The coefficient of variation was 2.8-7.8% (mean, 4.4%). All eight specimens (100%) at grade 1 (G1) were DNA diploid, but 20% and 85.7% of the G2 and G3 cells, respectively, were DNA aneuploid. In total, 15 of the 37 specimens were DNA aneuploid. All 17 pTa-pT1 specimens (100%) were DNA diploid, but 100% and 50% of the T2 and T3 tumors, respectively, were DNA aneuploid. CONCLUSION: One can now supplement a morphologic diagnosis with useful information using LSC of touch preparations of tumors obtained at surgery or of imprints of archived, frozen specimens. LSC provides excellent DNA histograms for surgical specimens and has great potential for clinical application in pathology.     

A new approach for the analysis of testicular cells using a laser scanning cytometer.

The laser scanning cytometer (LSC) is a new laboratory tool that offers increased sensitivity and specificity compared to traditional technology. By combining the properties of the advantages of flow cytometry and immunohistochemistry, LSC-based analysis allows the automated evaluation of testicular cells in general and meiosis in particular. Testicular cell smears with previous staining by propidium iodide were analyzed by LSC. The results were compared with those for flow cytometry. LSC is a new, applicable methodology for analyzing spermatogenesis schedule.     

Laser scanning cytometry for comet assay analysis

BACKGROUND: The comet assay (single-cell gel electrophoresis) is a sensitive method for evaluating nuclear DNA damage. Previously used evaluation methods for the comet assay are time consuming and have an inherent risk of biased selection of comets due to manual selection and categorization of comet images. Laser scanning cytometry (LSC), the principle of which is equivalent to flow cytometry, enables quantification of fluorescence emitted from the cells on a microscope slide. In the present study, we explored whether LSC could be used to determine the degree of DNA damage demonstrated by the comet assay. METHODS: DNA damage was induced by ultraviolet A irradiation of keratinocytes and visualized by the comet assay. The evaluation included (a) LSC determination of DNA-specific fluorescence in 1,000 comet heads (undamaged DNA), (b) image acquisition of comets by rescanning of the microscope slide, and (c) digital image analysis and computation of tail moment and DNA content in the comet tails. RESULTS: Cells with damaged DNA were observed in a sub-G(1) area because the comet head loses DNA to the tail. We found a strong inverse correlation between tail moment and DNA content per nucleus. CONCLUSIONS: LSC enables an automated method for cell recognition and evaluation of the comets, thus providing quantitative information about nuclear DNA damage without subjective selection of analyzed comets.     

Detection of localized caspase activity in early apoptotic cells by laser scanning cytometry

BACKGROUND: Caspase activation is a critical early step in the onset of apoptosis. Cell-permeable fluorogenic caspase substrates have proven valuable in detecting caspase activation by flow cytometry. Nevertheless, detection of early low-level caspase activation has been difficult using conventional area or peak fluorescence analysis by flow cytometry, despite the apparent presence of these cells as observed by microscopy. We describe a method utilizing maximum fluorescence pixel analysis by laser scanning cytometry (LSC) to detect early apoptotic cells. METHODS: The PhiPhiLux-G(1)D(2) caspase 3/7 substrate was used in combination with DNA dye exclusion and annexin V binding to identify several stages of apoptosis in EL4 murine thymoma cells by both traditional flow and LSC. LSC analysis of maximum pixel brightness in individual cells demonstrated an intermediate caspase-low subpopulation not detectable by flow or LSC integral analysis. LSC analysis of caspase activity was then carried out using the larger UMR-106 rat osteosarcoma cell line to determine if this apparent early caspase activity could be correlated with localized, punctate caspase activity observed by microscopy. RESULTS: The caspase-low subpopulation found in apoptotic EL4 cells was also observable in UMR-106 cells. Relocation to cells with low fluorescence due to caspase activity and subsequent examination by microscopy demonstrated that these latter cells indeed show punctate, highly localized caspase activation foci that might represent an early stage in caspase activation. CONCLUSIONS: Cells with low-level, localized caspase expression can be detected using maximum pixel analysis by LSC. This methodology allows an early step of apoptotic activation to be resolved for further analysis.     

Micronuclei assay by laser scanning cytometry

BACKGROUND: The micronuclei (MN) assay is used to assess the chromosomal/mitotic spindle damage induced by ionizing radiation or mutagenic agents in vivo or in vitro. Because visual scoring of MN is cumbersome semi-automatic procedures that relay either on flow cytometry or image analysis were developed: both offer some advantages but also have shortcomings. METHODS: In the present study laser scanning cytometer (LSC), the instrument that combines analytical capabilities of flow and image cytometry, has been adapted for quantitative analysis of MN. The micronucleation of human breast carcinoma MCF-7 and leukemic HL-60 and U-937 cells was induced by in vitro treatment with mitomycin C. Cellular DNA was stained with propidium iodide (PI), protein was counterstained with fluorescein isothiocyanate (FITC). Two approaches were used to detect MN: (a) the threshold contour was set based on the data from the photosensor measuring red fluorescence of PI and MN were identified on the bivariate PI versus PI/FITC fluorescence distributions by their characteristic position; (b) the threshold contour was set on the data from the sensor measuring FITC fluorescence which made it possible, using the LSC software dedicated for FISH analysis, to assay both the frequency and DNA content of individual MN within each measured cell. RESULTS: The capability of LSC to relocate MN for visual examination was useful to confirm their identification. Visual identification of MN combined with their multiparameter characterization that took into an account their DNA content and protein/DNA ratio made it possible establish the gating parameters that excluded objects that were not MN; 93.3+/-3.3 events within the selected gate were MN. It was also possible to successfully apply FISH software to characterize individual cells with respect to quantity of MN residing in them. The percentage of MN assayed by LSC correlated well with that estimated visually by microscopy, both for MCF-7 (r = 0.93) and HL-60 cells (r = 0.87). CONCLUSIONS: LSC can be used to obtain unbiased estimate of MN frequencies. Unlike flow cytometry, it also allows one to characterize individual cells with respect to frequency and DNA content of MN residing in these cells. These analytical capabilities of LSC may be helpful not only to score MN but also to study mechanisms by which clastogenic agents induce MN.     

Prediction of upper aerodigestive tract cancer by slide-based cytometry.

AIM: To evaluate slide-based cytometry in screening for and following up of carcinoma of the upper aerodigestive tract using swabs for a minimal-invasive approach. METHODS: Laser scanning cytometry (LSC) was used for multiparametric analysis of cells stained for cytokeratin and DNA to determine the DNA-index (DI) of the tumor cells. Histograms with 0.95 < DI < 1.05 and 1.9 < DI < 2.1 were defined as DNA euploid and any other DI as DNA aneuploid. After subsequent HE-staining, single cells were relocalized in order to document morphology. Conventional cytology was also performed on a subset of the slides. Routine histopathology of parallel biopsies served as gold standard in all cases. RESULTS: 115 swabs from 109 patients were obtained from the entire upper aerodigestive tract. 16 swabs were classified as insufficient for LSC. In the remaining 99 specimens, 1 benign lesion was misclassified as malignant, while 61 of the 75 malignant lesions were correctly identified. This corresponds to predictive values of 98.4% and 62.2% for the detection of malignant and benign samples by LSC. CONCLUSION: This pilot study demonstrates the validity of LSC screening for the identification of tumor malignancy in the upper aerodigestive tract from swab collected cytological material.     

Inference of cell cycle-dependent proteolysis by laser scanning cytometry

Mechanisms that couple protein turnover to cell cycle progression are critical for coordinating the events of cell duplication and division. Despite the importance of cell cycle-regulated proteolysis, however, technologies to measure this phenomenon are limited, and typically involve monitoring cells that are released back into the cell cycle after synchronization. We describe here the use of laser scanning cytometry (LSC), a technical merger between fluorescence microscopy and flow cytometry, to determine cell cycle-dependent changes in protein stability in unperturbed, asynchronous, cultures of mammalian cells. In this method, the ability of the LSC to accurately measure whole cell fluorescence is employed, together with RNA fluorescence in situ hybridization and immunofluorescence, to relate abundance of a particular RNA and protein in a cell to its point at the cell cycle. Parallel monitoring of RNA and protein levels is used, together with protein synthesis inhibitors, to reveal cell cycle-specific changes in protein turnover. We demonstrate the viability of this method by analyzing the proteolysis of two prominent human oncoproteins, Myc and Cyclin E, and argue that this LSC-based approach offers several practical advantages over traditional cell synchronization methods.     

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.     

Unique analytical capabilities of laser scanning cytometry (LSC) that complement flow cytometry

Flow cytometry has become an indispensable instrumentation in many disciplines of biology and medicine. There are some limitations of flow cytometry, inherent to the fact that the cells are measured in flow, which limit its usefulness in some applications. The microscope-based laser scanning cytometer (LSC) has many features similar to flow cytometry but few restrictions of the latter and therefore it is useful in many new applications. This review briefly outlines the applications that are unique to LSC, particularly related to its morphometric capabilities and the possibility of cell relocation. Potential future applications of LSC are also discussed.     

Laser scanning cytometry (LCS) allows detailed analysis of the cell cycle in PI stained human fibroblasts (TIG-7)

We have demonstrated a method for the in situ determination of the cell cycle phases of TIG-7 fibroblasts using a laser scanning cytometer (LSC) which has not only a function equivalent to flow cytometry (FCM) but also has a capability unique in itself. LSC allows a more detailed analysis of the cell cycle in cells stained with propidium iodide (PI) than FCM. With LSC it is possible to discriminate between mitotic cells and G₂ cells, between post-mitotic cells and G₁ cells, and between quiescent cells and cycling cells in a PI fluorescence peak (chromatin condensation) vs. fluorescence value (DNA content) cytogram for cells stained with PI. These were amply confirmed by experiments using colcemid and adriamycin. We were able to identify at least six cell subpopulations for PI stained cells using LSC; namely G₁, S, G₂, M, postmitotic and quiescent cell populations. LSC analysis facilitates the monitoring of effects of drugs on the cell cycle.     

Role of ancillary techniques in diagnosing and subclassifying non-Hodgkin''s lymphomas on fine needle aspiration cytology

Non-Hodgkin's lymphomas (NHL) are tumours of the lymphoid cells. During the process of development of lymphoid cells, neoplasia may evolve at any point. Neoplastic cells usually carry the imprint of cell of origin at the stage of origin. Various types of NHL may have similar morphology with wide variation in origin, immunophenotype and other biological features. Different ancillary laboratory techniques may help to overcome the limitations of morphology in this aspect. The commonly used ancillary techniques in lymphomas are immunocytochemistry (IC), flow cytometry, Southern blot (SB) technique, polymerase chain reaction (PCR) and fluorescent in situ hybridization (FISH). In addition, laser scanning cytometry (LSC) and DNA microarray technologies are in the research phase. Various laboratory techniques are used for immunophenotyping, demonstration of monoclonality, identification of chromosomal translocation, assessment of cell kinetics and expression of mRNA in the tumour cells. Flow cytometry helps in rapid immunophenotying of NHL and it has an added advantage over IC in recognizing the co-expression of CD markers. Fine needle aspiration cytology (FNAC) combined with flow immunophenotyping may help us to diagnose and subclassify certain NHLs, such as follicular lymphoma and mantle cell lymphoma, which were previously recognized as pure morphological entities. Loss of morphology is one of the important limitations of flow cytometry. LSC can overcome this limitation by studying morphology along with the immunophenotyping pattern of individual cells. Chromosomal changes in NHL can be identified by SB, PCR and FISH. Molecular diagnosis of NHL helps in diagnosis, subclassification, prognostic assessment and even in planning of therapy. DNA microarray is a relatively newer and promising technology. It gives information about the expression of several thousands of genes in a tumour in a single experiment. In the near future, FNAC combined with ancillary techniques may play a major role in diagnosis, subclassification and management of lymphomas.     

Translocation of Bax to mitochondria during apoptosis measured by laser scanning cytometry

BACKGROUND: During induction of apoptosis, the pro-apoptotic member of the Bcl-2 protein family (Bax) undergoes translocation to the mitochondria. The translocation, which leads to accumulation of Bax in the mitochondrial intermembrane space, appears to be the critical event determining release of cytochrome c to cytosol: the latter event triggers the irreversible steps of apoptosis, namely, the activation of caspases and the initiation of the degradation of many proteins. The aim of this study was to utilize the morphometric capabilities of the laser scanning cytometer (LSC) and adapt this instrument to detect and measure in situ the process of translocation of Bax to mitochondria. METHODS: Human breast carcinoma MCF-7 cells growing on microscope slides were treated with the DNA topoisomerase I inhibitor, camptothecin (CPT). CPT is known to induce apoptosis preferentially of S-phase cells. The cells were fixed and permeabilized on the slides, their DNA was stained with propidium iodide (PI), Bax was detected immunocytochemically with the fluoresceinated antibody, and red and green fluorescence emission was measured by the LSC. RESULTS: Prior to induction of apoptosis, Bax was uniformly and diffusely dispersed in the cell nucleus and cytoplasm. Its translocation and accumulation in mitochondria in cells undergoing apoptosis were detected and measured by the LSC as the increase in intensity of maximal pixel of Bax immunofluorescence. Bivariate analysis of DNA content versus maximal pixel of Bax fluorescence revealed that the CPT-induced Bax translocation into mitochondria was preferential to S-phase cells. Total cellular Bax immunofluorescence measured by flow cytometry, however, was increased in all phases of the cycle without a preference to S-phase cells. CONCLUSION: Changes in abundance and localization of particular proteins that undergo translocation within the cell, leading to their altered local density, may be conveniently detected by the LSC by taking advantage of its morphometric capabilities. Measurement of total cellular Bax immunofluorescence by flow cytometry combined with analysis of its translocation by LSC revealed that apoptosis of S-phase cells induced by CPT was unrelated to overall Bax abundance per cell but correlated with its accumulation in mitochondria.     

Fine needle aspiration cytology of metastatic malignant rhabdoid tumor

The diagnosis and management of pediatric neoplasms using fine needle aspiration (FNA) has been neglected as compared to neoplasms occurring in adults. A case of metastatic malignant rhabdoid tumor diagnosed by FNA cytology is presented, and the cytologic morphology, which to our knowledge has not previously been reported, is described. The ultrastructural findings in the histologic specimen are also depicted. This case demonstrates the feasibility and need for further exploration of the use of FNA in pediatric oncology.     

DNA宏条形码技术在食草动物食性研究中的应用

随着测序技术的快速发展,整合DNA条形码和高通量测序的DNA宏条形码技术已经成为当前研究热点之一,在食草动物的食性鉴定中有很大潜力.放牧动物食性研究是动物营养学和草地生态学领域的重要研究内容.而与传统食性研究方法相比,宏条形码技术可通过对植物DNA条形码的高通量测序,获得样本中的物种组成进而分析动物食性.介绍了传统食性...