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Cell proliferation assays provide a critical piece of the puzzle when evaluating cell health, cytotoxicity, and the efficacy of anti-cancer drugs. Moreover, much of our current knowledge of the immune system derives from the ability to initiate an ex vivo immune response in isolated T lymphocytes, triggering their proliferation. By labeling cells in a population with a fluorescent dye that is divided evenly between two daughter cells following cell division, researchers can quantify cell proliferation through multiple generations using a high-throughput fluorescence-based platform such as flow cytometry (Figure 1).
Like CFSE, the dyes in the Invitrogen™ CellTrace™ Cell Proliferation Kits—including CellTrace Violet, CellTrace Yellow, and CellTrace Far Red—facilitate both in vivo and in vitro cell proliferation analyses by flow cytometry. CellTrace dyes easily cross the plasma membrane and covalently bind inside cells, where the stable, well-retained fluorescent conjugate offers a reliable fluorescent signal without significantly affecting morphology or physiology. Importantly, these dyes produce fluorescent staining with very little variation between cells within a generation, allowing each generation to be reliably distinguished. The intense fluorescent staining provided by CellTrace dyes permits the visualization of proliferating cells through a minimum of six generations, even after several days in a cell culture environment or following fixation. There are several criteria to consider when choosing the right cell tracer for an experiment, and the following sections focus on the most important technical factors. Also see page 30 for a summary of a recent journal article that discusses methods to assess cell tracing reagents.
Cell tracers are used on living, dividing cells and therefore must not have a significant impact on cell health and viability. For example, the concentration of the traditional cell tracer CFSE must be carefully optimized for each cell line and culture condition because high concentrations of CFSE have been reported to impact cell viability and division, whereas low concentrations may limit the number of cell generations detected [1]. At the recommended working concentration of 5 μM, CFSE-labeled Jurkat cells had less than 15% viability after 6 days of staining (Figure 2). Titration studies of CFSE labeling of Jurkat cells demonstrated that concentrations between 0.5 μM and 1 μM were optimal for maintaining cell viability, and concentrations above 2 μM induced toxicity (Figure 2A). In contrast, the other CellTrace dyes did not exhibit toxic side effects after 6 days of staining at the concentrations tested (Figure 2B). In particular, CellTrace Violet, CellTrace Yellow, and CellTrace Far Red showed minimal effects on cell viability at concentrations of 5 μM, 10 μM, and 1 μM, respectively, substantially increasing the window of effective reagent concentration for cell proliferation analysis.
CFSE is known to undergo nonspecific cell-to-cell dye transfer. This dye transfer decreases the observed resolution of cell generations, thereby reducing accuracy when identifying cell division populations. Although most succinimidyl esters also undergo membrane-exchange mechanisms that negatively affect peak resolution, CellTrace Violet dye is unique in that it shows minimal transfer between adjacent cells [2]. Consequently, CellTrace Violet dye provides better resolution between division peaks and therefore more accurate quantitation in generational analysis.
To enable detection of cell proliferation through many generations, the ideal cell tracer should produce a bright fluorescent signal that is still detectable after several rounds of division, despite the dilution of the signal with each successive generation. CFSE-labeled cells, however, show a significant decrease in fluorescence after the first 24 hours. It has been reported that this is likely due to the cells’ clearing of short-lived proteins that were initially labeled with the dye [3]. Although this loss of fluorescence may not affect every experiment in which CFSE is used, it suggests that there will be less tracer available for generational analysis over time. In contrast, independent testing by Joseph Tario Jr. at the Roswell Park Cancer Institute demonstrates that, unlike CFSE, neither CellTrace Violet dye nor CellTrace Far Red dye shows the unwanted initial decrease in fluorescence (Figure 3).
Cell proliferation assays are often used in concert with other cell function assays to provide a more informative picture of the state of the cell. Although widely used for proliferation analysis, CFSE (excitation/ emission = 492/517 nm) requires one of the most popular flow cytometry channels— the same channel used by FITC, Alexa Fluor™ 488 dye, and GFP. In contrast, the CellTrace Violet, CellTrace Yellow, and CellTrace Far Red dyes are excited by the 405 nm, 532 (or 561) nm, and 633 (or 635) nm lasers, respectively. Not only do these tracers allow for greater flexibility in flow cytometry panel design, but each dye can be multiplexed with 488 nm–excitable green-fluorescent probes. Figure 4 shows a multiplex experiment that incorporates CellTrace Yellow dye for measuring cell proliferation, Invitrogen™ FxCycle™ Violet Stain for fixed-cell DNA content analysis, the Invitrogen™ Click-iT™ Plus EdU Alexa Fluor™ 488 Flow Cytometry Assay Kit for detecting newly synthesized DNA, Invitrogen™ LIVE/DEAD™ Fixable Near-IR Dead Cell Stain for assessing viability, and a fluorescent antibody conjugate for immunophenotyping. This multicolor analysis demonstrates the depth of information that can be gathered when additional functional reagents are used to assay the cell population of interest.
When compared with traditional cell tracers such as CFSE, the CellTrace dyes provide significant advantages, including their low toxicity and bright and stable fluorescence. In particular, CellTrace Violet dye has been cited in several comparative studies as superior to CFSE for cell proliferation analyses [2,4].
仅供科研使用,不可用于诊断目的。