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.     

Quantitative image based apoptotic index measurement using multispectral imaging flow cytometry: a comparison with standard photometric methods

Morphological characterization by microscopy remains the gold standard for accurately identifying apoptotic cells using characteristics such as nuclear condensation, nuclear fragmentation, and membrane blebbing. However, quantitative measurement of apoptotic morphology using microscopy can be time consuming and can lack objectivity and reproducibility, making it difficult to identify subtle changes in large populations. Thus the apoptotic index of a sample is commonly measured by flow cytometry using a variety of fluorescence intensity based (photometric) assays which target hallmarks of apoptosis with secondary markers such as the TUNEL (Terminal Deoxynucleotide Transferase dUTP Nick End Labeling) assay for detection of DNA fragmentation, the Annexin V assay for surface phosphatidylserine (PS) exposure, and fluorogenic caspase substrates to detect caspase activation. Here a novel method is presented for accurate quantitation of apoptosis based on nuclear condensation, nuclear fragmentation, and membrane blebbing using automated image analysis on large numbers of images collected in flow by the ImageStream multispectral imaging cytometer. Additionally the measurement of nuclear fragmentation correlates with the secondary methods of detection of apoptosis over time, indicating that it is also an early marker for apoptosis. False-positive and false-negative events associated with each photometric flow cytometry based method are quantitated and can be automatically removed/included where appropriate. Acquisition of multi-spectral imagery on large numbers of cells couples the quantitative advantage of flow cytometry with the accuracy of morphology-based algorithms allowing more complete and robust analysis of apoptosis.     

Measurement of DNA damage associated with apoptosis by laser scanning cytometry.

BACKGROUND: Phosphatidylserine (PS) binding by annexin V (AV) is an early membrane marker of apoptosis. Using laser scanning cytometry (LSC) and the comet assay, we showed that the DNA of AV(+) cells is so highly fragmented that it cannot be quantified by the comet assay (Bacso et al.: Cancer Res 60:4623-8, 2000). METHODS: The "halo" assay was used instead of the comet assay to quantify DNA damage associated with apoptosis. The LSC was used to measure both AV fluorescence and DNA damage on the same Jurkat cells following treatment with anti-Fas. The data from both sets of measurements were merged, allowing direct correlation of membrane and nuclear markers of cell death. RESULTS: AV(+) cells had significant DNA damage determined by the ratio between nuclear DNA and peripheral (migrated) DNA. Cells in the early and late stages of apoptosis could be discriminated on the basis of DNA content. In addition, it was possible to distinguish between apoptotic and necrotic cells in the AV(+) propidium iodide-positive population based on DNA content and DNA damage. The addition of specific inhibitors for caspases-8, 9, and 3 blocked both PS externalization and DNA fragmentation, indicating these events are downstream from caspase activation. CONCLUSIONS: This technique allows accurate distinction between apoptotic and necrotic cells and cytometric grading of apoptosis.     

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.     

Detection of caspases activation by fluorochrome-labeled inhibitors: Multiparameter analysis by laser scanning cytometry

BACKGROUND: The fluorochrome-labeled inhibitors of caspases (FLICA) were recently used as markers of activation of these enzymes in live cells during apoptosis (Bedner et al.: Exp Cell Res 259:308-313, 2000). The aims of this study were to (a) explore if FLICA can be used to study intracellular localization of caspases; (b) combine the detection of caspase activation with analysis of the changes with cell morphology detected by microscopy and laser scanning cytometry (LSC); and (c) adapt the assay to fixed cells that would enable correlation, by multiparameter analysis, of caspase activation with the cell attributes that require cell permeabilization in order to be measured. METHODS: Apoptosis of human MCF-7, U-937, or HL-60 cells was induced by camptothecin (CPT) or tumor necrosis factor-alpha (TNF-alpha) combined with cycloheximide (CHX). Binding of FLICA to apoptotic versus nonapoptotic cells was studied in live cells as well as following their fixation and counterstaining of DNA. Intensity of cell labeling with FLICA and DNA-specific fluorochromes was measured by LSC. RESULTS: Exposure of live cells to FLICA led to selective labeling of cells that had morphological changes characteristic of apoptosis. The FLICA labeling withstood cell fixation and permeabilization, which made it possible to stain DNA and measure its content for identification of the cell cycle position of labeled cells. When fixed cells were treated with FLICA, both apoptotic and nonapoptotic cells became strongly labeled and the labeling pattern was consistent with the localization of caspases as reported in the literature. A translocation of the FLICA binding targets from mitochondria to cytosol was seen in the MCF-7 cells treated with CPT. FLICA binding was largely (> 90%) prevented by the substrates of the caspases or by the unlabeled caspase inhibitors having the same peptide moiety as the respective FLICA. CONCLUSIONS: The detection of caspase activation combined with cell permeabilization requires exposure of live cells to FLICA followed by their fixation. Cell reactivity with the respective FLICA, under these conditions, identifies the activated caspases and makes it possible to correlate their activation with the cell cycle position and other cell attributes that can be measured only after cell fixation/permeabilization. FLICA can also be used to study intracellular localization of caspases, including their translocation.     

Caspase 8 activity in membrane blebs after anti-Fas ligation.

Previous studies of thymocyte apoptosis using a series of cell-permeable fluorogenic peptide substrates showed that Fas cross-linking triggered a caspase cascade in which cleavage of the IETDase (caspase 8-selective) substrate was the earliest caspase activity measured by flow cytometry. This result was expected in light of the abundant evidence for caspase 8 activation as an initiating event in the Fas death pathway. However, when apoptosis was induced by anti-Fas in CTL and the caspase cascade examined by this approach, IETDase activation followed increases in LEHDase, YVHDase, and VEIDase activities (selective for caspases 9, 1, and 6, respectively). When examined by confocal microscopy, anti-Fas-treated CTL showed the early appearance of IETDase-containing plasma membrane vesicles and their release from the CTL surface, followed by activation of other caspase activities in the cell interior. Since these vesicles were not included in the flow cytometry analysis, the early IETDase activity had been underestimated. In contrast to anti-Fas, induction of apoptosis in these CTL by IL-2 withdrawal resulted in early IETDase activity in the cytoplasm, with no plasma membrane vesiculation. Thus, anti-Fas-induced initiation of caspase activity at the plasma membrane may in some cells result in local proteolysis of submembrane proteins, leading to generation of membrane vesicles that are highly enriched in active caspase 8.     

A conformational change in cytochrome c of apoptotic and necrotic cells is detected by monoclonal antibody binding and mimicked by association of the native antigen with synthetic phospholipid vesicles

By flow cytometry, a conformational change in mouse cytochrome c (cyt c) of apoptotic and necrotic T hybridoma cells was detected using a monoclonal antibody (mAb) that recognizes the region around amino acid residue 44 on a non-native form of the protein. The conformational change in cyt c is an early event in apoptosis, which can be identified in pre-apoptotic cells that are negative for other indicators of apoptosis. Since the mAb did not bind fixed and permeabilized live cells and did not immunoprecipitate soluble cyt c extracted with detergent from dead cells, it appears to recognize cyt cbound in a detergent-sensitive complex to other cellular components. Coincidentally, the mAb was also shown by competitive enzyme-linked immunosorbent assay to bind cyt c associated with synthetic phosphatidic acid vesicles. This suggests that the conformational change of cyt c in dying cells could be due to its association with intracellular membranes that are, perhaps, altered in cell death. By immunofluorescent confocal microscopy, conformationally altered cyt c in post-apoptotic T hybridoma cells showed a punctate distribution, indicating that it remained associated with mitochondria. Furthermore, the heavy membrane fraction of post-apoptotic cells but not of live cells was functional in caspase activation. This suggests that membrane-bound cyt c is the relevant caspase coactivation factor in the T hybridoma cells.     

Flow cytometry detection of caspase 3 activation in preapoptotic leukemic cells

BACKGROUND: Procaspase 3 is a constitutive proenzyme that is activated by cleavage during apoptosis. The resulting enzyme is able to cleave several target proteins after the second aspartate of a DEVD sequence common to all the substrates of caspases 3 and 7 (DEVDase). Because active caspase 3 is a common effector in several apoptotic pathways, it may be a good marker to detect (pre-)apoptotic cells by flow cytometry (FCM). Materials and Methods Apoptosis was induced in U937 or bone marrow mononuclear cells by daunorubicin (DNR), idarubicin (IDA), or camptothecin (CAM). Viable and apoptotic cells were sorted by FCM on the basis of either fluorescein isothiocyante (FITC)-annexin V binding or DiOC6(3) accumulation. DEVDase activity was measured in sorted populations by spectrofluorometry. Cleaved caspase 3 was labeled in situ with phycoerythrin (PE)-conjugated anti-activated caspase 3 antibodies and analyzed by FCM. RESULTS: DEVDase activity was detected in sorted viable CAM- and DNR-treated U937 cells, demonstrating that a partial caspase activation occurred earlier than phosphatidyl-serine exposure and mitochondrial membrane potential dissipation. The presence of a low amount of active caspase 3 in the treated viable cells was confirmed in situ with PE-conjugated anti-active caspase 3 antibodies. The same antibody was used in combination with FITC-annexin V and CD45-PC5 to study caspase 3 activation in acute leukemia blast cells after in vitro DNR and IDA treatment. Both anthracyclines induced a caspase 3-dependent apoptosis that was more efficient in blast cells than in contaminating lymphocytes. CONCLUSIONS: These results demonstrate that anti-active caspase 3 labeling can be an alternative to fluorogenic substrates to efficiently detect early apoptosis by FCM in heterogeneous samples. They also confirm that anthracyclines induce blast cell apoptosis by a caspase 3-dependent pathway.     

Caspase Activation Is an Early Event in Anthracycline-Induced Apoptosis and Allows Detection of Apoptotic Cells before They Are Ingested by Phagocytes

An increasing number of methods are being described to detect apoptotic cells. However, attempts to detect apoptotic cells in clinical samples are rarely successful. A hypothesis is that apoptotic cells are cleared from the circulation by phagocytosis before they become detectable by conventional morphological or cytometric methods. Using LR73 adhering cells as phagocytes in a model ofin vitrophagocytosis, we found that phagocytosis of daunorubicin (DNR)-treated U937, HL60, or K562 leukemia cell lines occurred prior to phosphatidylserine externalization, DNA hydrolysis, chromatin condensation, nuclear fragmentation, or mitochondrial potential alteration. Moreover DNR-treated K562 cells were eliminated by phagocytes while apoptosis was never observed by any of the above methods. By contrast, using a fluorometric batch analysis assay to detect caspase activity in ceramide- or DNR-treated cells (fluorogenic substrate for caspase), we found that caspase activity increased in apoptosis-committed cells before they were detected by flow cytometry or recognized by phagocytes. Similarly a caspase activity increase was detected in circulating mononuclear cells of leukemic patients 15 h after the beginning of anthracyclin treatment. We suggest that recent findings on enzymatic events (caspase activation) occurring in the early events of apoptosis must now allow the development of new markers for apoptosis, irrespective of the morphological features or internucleosomal fragmentation which are late events in apoptosis.     

Granzyme B activity in target cells detects attack by cytotoxic lymphocytes

Lymphocyte-mediated cytotoxicity via granule exocytosis operates by the perforin-mediated transfer of granzymes from CTLs and NK cells into target cells where caspase activation and other death pathways are triggered. Granzyme B (GzB) is a major cytotoxic effector in this pathway, and its fate in target cells has been studied by several groups using immunodetection. In this study, we have used a newly developed cell-permeable fluorogenic GzB substrate to measure this protease activity in three different living targets following contact with cytotoxic effectors. Although no GzB activity is measurable in CTL or NK92 effector cells, this activity rapidly becomes detectable throughout the target cytoplasm after effector-target engagement. We have combined the GzB substrate with a second fluorogenic substrate selective for caspase 3 to allow both flow cytometry and fluorescence confocal microscopy studies of cytotoxicity. With both effectors, caspase 3 activity appears subsequent to that of GzB inside all three targets. Overexpression of Bcl-2 in target cells has minimal effects on lysis, NK- or CTL-delivered GzB activity, or activation of target caspase 3. Detection of target GzB activity followed by caspase 3 activation provides a unique readout of a potentially lethal injury delivered by cytotoxic lymphocytes.     

重组艰难梭菌毒素B对小鼠结肠癌CT26细胞的诱导凋亡作用

本文探讨了重组艰难梭菌毒素B(rTcd B)对小鼠结肠癌CT26细胞的诱导凋亡作用。采用不同浓度rTcd B处理CT26细胞, 通过MTT法检测细胞增殖抑制率; 比色法测定Caspase 3活性; 细胞形态学和流式细胞技术检测细胞凋亡。结果表明, rTcd B显著抑制了CT26细胞的增殖, 并呈时间?剂量依赖性; Caspase 3活性在处理6 h后显著升高, 至18 h达到最大值, 与对照组相比差异显著, 具有统计学意义(P<0.05); 荧光显微镜观察到典型细胞凋亡形态学变化, 细胞膜内侧的磷脂酰丝氨酸(PS)异位到了膜外侧, 细胞膜呈明亮的绿色荧光; 通过流式细胞仪检测结果表明, 细胞凋亡率呈时间?剂量依赖性增加。实验结果表明, 重组艰难梭菌毒素B能够诱导小鼠结肠癌CT26细胞凋亡。     

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.     

Simultaneous analysis of radio-induced membrane alteration and cell viability by flow cytometry

BACKGROUND: Modifications of intracellular transfer, resulting from a loss of membrane integrity may contribute toward setting the cell onto the pathway of apoptosis. METHODS: We have developed an original technique of measuring simultaneously, with flow cytometry, changes in membrane fluidity and cell death status. Our aim was to assess the extent to which radio-induced cell death and membrane alterations are linked. Investigations were performed on lymphocytes 24 h after whole human blood gamma-irradiation. RESULTS: Our results confirmed the expected increase in the percentage of apoptotic cells as a function of dose, but revealed that the percentage of necrotic cells appeared stable after irradiation. At the same time, the fluorescence anisotropy of the living lymphocyte subpopulation decreased significantly and dose dependently as measured 24 h post-irradiation. With TMA-DPH, the anisotropy index of apoptotic lymphocytes was always lower than that of the viable lymphocyte subpopulation. On the other hand, 1,6-diphenyl-1,3,5-hexatriene (DPH) anisotropy was similar in apoptotic and viable cells after irradiation. These findings suggest that apoptotic lymphocytes are characterised by a membrane fluidization that mainly occurs on the cell membrane surface. CONCLUSION: Our study made technical advances in using cytometric fluorescence anisotropy measurement as an early biological indicator of apoptosis after cellular exposure to ionising radiation.     

Rapid caspase-dependent cell death in cultured human breast cancer cells induced by the polyamine analogue N(1),N(11)-diethylnorspermine.

The spermine analogue N(1),N(11)-diethylnorspermine (DENSPM) efficiently depletes the cellular pools of putrescine, spermidine and spermine by down-regulating the activity of the polyamine biosynthetic enzymes and up-regulating the activity of the catabolic enzyme spermidine/ spermine N(1)-acetyltransferase (SSAT). In the breast cancer cell line L56Br-C1, treatment with 10 microm DENSPM induced SSAT activity 60 and 240-fold at 24 and 48 h after seeding, respectively, which resulted in polyamine depletion. Cell proliferation appeared to be totally inhibited and within 48 h of treatment, there was an extensive apoptotic response. Fifty percent of the cells were found in the sub-G(1) region, as determined by flow cytometry, and the presence of apoptotic nuclei was morphologically assessed by fluorescence microscopy. Caspase-3 and caspase-9 activities were significantly elevated 24 h after seeding. At 48 h after seeding, caspase-3 and caspase-9 activities were further elevated and at this time point a significant activation of caspase-8 was also found. The DENSPM-induced cell death was dependent on the activation of the caspases as it was inhibited by the general caspase inhibitor Z-Val-Ala-Asp fluoromethyl ketone. The results are discussed in the light of the L56Br-C1 cells containing mutated BRCA1 and p53, two genes involved in DNA repair.     

Withanolide induces apoptosis in HL-60 leukemia cells via mitochondria mediated cytochrome c release and caspase activation

The present study is on the growth inhibitory effect of Withania somnifera methanolic leaf extract and its active component, withanolide on HL-60 promyelocytic leukemia cells. The decrease in survival rate of HL-60 cells was noted to be associated with a time dependent decrease in the Bcl-2/Bax ratio, leading to up regulation of Bax. Both the crude leaf extract and the active component activated the apoptotic cascade through the cytochrome c release from mitochondria. The activation of caspase 9, caspase 8 and caspase 3 revealed that caspase was a key mediator in the apoptotic pathway. DNA fragmentation analysis revealed typical ladders as early as 12h indicative of caspase 3 role in the apoptotic pathway. Flow cytometry data demonstrated an increase of sub-G1 peak upon treatment by 51% at 24h, suggesting the induction of apoptotic cell death in HL-60 cells.     

Rhodamine 110-linked amino acids and peptides as substrates to measure caspase activity upon apoptosis induction in intact cells.

Caspases (cysteine aspartate-specific proteases) are a structurally related group of cysteine proteases that cleave peptide bonds following specific recognition sequences. They play a central role in activating apoptosis of vertebrate cells. To measure apoptosis induced by various stimuli and at an early apoptotic stage, caspases are an ideal target. This is especially the case when apoptotic cells have to be analyzed ex vivo before phagocytes remove them. A new and sensitive caspase assay is based on a substrate that contains only aspartate residues linked to rhodamine 110. With this and similar substrates, we are able to detect intracellular caspase activation by flow cytometry after apoptosis induction in intact hematopoetic cell lines.     

Detection of caspase activation in situ by fluorochrome-labeled caspase inhibitors

Apoptosis is dependent on the activation of a group of proteolytic enzymes called caspases. Caspase activation can be detected by immunoblotting using caspase-specific antibodies or by caspase activity measurement employing pro-fluorescent substrates that become fluorescent upon cleavage by the caspase. Most of these methods require the preparation of cell extracts and, therefore, are not suitable for the detection of active caspases within the living cell. Using FAM-VAD-FMK, we have developed a simple and sensitive assay for the detection of caspase activity in living cells. FAM-VAD-FMK is a carboxyfluorescein (FAM) derivative of benzyloxycarbonyl-valine-alanine-aspartic acid-fluoromethyl ketone (zVAD-FMK), which is a potent broad-spectrum inhibitor of caspases. FAM-VAD-FMK enters the cell and irreversibly binds to activated caspases. Cells containing bound FAM-VAD-FMK can be analyzed by flow cytometry, fluorescence microscopy, or a fluorescence plate reader. Using FAM-VAD-FMK, we have measured caspase activation in live non-adherent and adherent cells. We show that FAM-VAD-FMK labeled Jurkat and HeLa cells that had undergone apoptosis following treatment with camptothecin or staurosporine. Non-stimulated negative control cells were not stained. Pretreatment with the general caspase inhibitor zVAD-FMK blocked caspase-specific staining in induced Jurkat and HeLa cells. Pretreatment of staurosporine-induced Jurkat cells with FAM-VAD-FMK inhibited affinity labeling of caspase-3, -6, and -7, blocked caspase-specific cell staining, and led to the inhibition of apoptosis. In contrast, the fluorescent control inhibitor FAM-FA-FMK had no effect. Measurement of caspase activation in 96-well plates showed a 3- to 5-fold increase in FAM-fluorescence in staurosporine-treated cells compared to control cells. In summary, we show that FAM-VAD-FMK is a versatile and specific tool for detecting activated caspases in living cells.     

Antimycin A-induced killing of HL-60 cells: apoptosis initiated from within mitochondria does not necessarily proceed via caspase 9.

BACKGROUND: Antimycin A (AMA) inhibits mitochondrial electron transport, collapses the mitochondrial membrane potential, and causes the production of reactive oxygen species. Previous work by me and my colleagues has demonstrated that AMA causes an array of typical apoptotic phenomena in HL-60 cells. The hypothesis that AMA causes HL-60 apoptosis by the intrinsic apoptotic pathway has now been tested. METHODS: Z-LEHD-FMK and Z-IETD-FMK were used as specific inhibitors of the initiator caspases 9 and 8, respectively. Caspase 3 activation, DNA fragmentation, and cellular disintegration were measured by flow cytometry. Cytochrome c release, chromatin condensation, and nuclear fragmentation were measured by microscopy. RESULTS: AMA caused mitochondrial cytochrome c release and neither Z-LEHD-FMK nor Z-IETD-FMK inhibited that. In the absence of caspase inhibition there was a very close correlation between cytochrome c release and caspase 3 activation. Z-LEHD-FMK blocked caspase 3 activation but enhanced DNA fragmentation and failed to stop nuclear or cellular disintegration. Z-IETD-FMK also blocked caspase 3 activation but, in contrast to Z-LEHD-FMK, delayed DNA fragmentation and disintegration of the nucleus and the cell. CONCLUSIONS: The hypothesis to explain AMA-induced HL-60 apoptosis was clearly inadequate because: (a) caspase 9 inhibition did not prevent DNA fragmentation or cell death, (b) apoptosis proceeded in the absence of caspase-3 activation, (c) the main pathway leading to activation of the executioner caspases was by caspase-8 activation, but caspase 8 inhibition only delayed apoptosis, and (d) activation of caspases 8 and 9 may be necessary for caspase-3 activation. Thus, in this cell model, apoptosis triggered from within the mitochondria does not necessarily proceed by caspase 9, and caspase 3 is not critical to apoptosis. The results provide further evidence that, when parts of the apoptotic network are blocked, a cell is able to complete the program of cell death by alternate pathways.     

Effects of caspase inhibitors (z-VAD-fmk, z-VDVAD-fmk) on Nile Red fluorescence pattern in 7-ketocholesterol-treated cells: investigation by flow cytometry and spectral imaging microscopy.

BACKGROUND: The 7-ketocholesterol (7KC)-induced cell death has some characteristics of apoptosis and is associated with polar lipid accumulation. So, we investigated the effects of the broad-spectrum caspase inhibitor z-VAD-fmk and of the caspase-2 inhibitor z-VDVAD-fmk on lipid profile evaluated by staining with Nile Red (NR). METHODS: The 7KC-treated human monocytic U937 cells were cultured in the absence or in the presence of the caspase inhibitors z-VAD-fmk or z-VDVAD-fmk. When staining with NR is performed, neutral and polar lipids have yellow and orange/red emission, respectively, and fluorescence was then analyzed by flow cytometry (FCM) and by confocal laser scanning microscopy (CLSM) combined with subsequent image processing. The 3D-image sequences were obtained by means of CLSM using spectral analysis, and were analyzed by the factor analysis of medical image sequences algorithm to differentiate spectra inside mixed fluorescence emission and get corresponding specific images. RESULTS: By FCM, comparatively to untreated cells, higher percentages of red fluorescent cells were identified in 7KC-treated cells. Factor curves and images reveal orange and red fluorescence emissions in 7KC-treated cells and show yellow, orange, and red fluorescence emissions in 7KC-treated cells cultured in the presence of z-VAD-fmk or z-VDVAD-fmk. CONCLUSIONS: Our data support that investigation by FCM and by spectral analysis in CLSM associated with subsequent image processing provides useful tools to determine the effect of caspase inhibitors on lipid content evaluated with NR. They also favor the hypothesis of relationships between caspase activity and polar lipid accumulation.     

Synthesis and characterization of BODIPY-labeled colchicine

Two BODIPY-labeled colchicine derivatives were synthesized and shown to bind to tubulin but only partially inhibit tubulin polymerization in the presence of GTP. Cytotoxicity studies were carried out in HeLa, HepG2, Raji and Vero cells. Apoptosis-inducing properties were determined by caspase 3/7 activity and flow cytometry and interactions between the derivatives and tubulin were verified by fluorescence microscopy of living cells.