calcein-am and 2--7--bis-(2-carboxyethyl)-5(6)-carboxyfluorescein-acetoxymethyl-ester

The multidrug resistance protein (MRP) family encodes a diverse repertoire of ATP-binding cassette (ABC) transporters with multiple roles in development, disease, and homeostasis. Understanding MRP evolution is central to unraveling their roles in these diverse processes. Sea urchins occupy an important phylogenetic position for understanding the evolution of vertebrate proteins and have been an important invertebrate model system for study of ABC transporters. We used phylogenetic analyses to examine the evolution of MRP transporters and functional approaches to identify functional forms of sea urchin MRP1 (also known as SpABCC1). SpABCC1, the only MRP homolog in sea urchins, is co-orthologous to human MRP1, MRP3, and MRP6 (ABCC1, ABCC3, and ABCC6) transporters. However, efflux assays revealed that alternative splicing of exon 22, a region critical for substrate interactions, could diversify functions of sea urchin MRP1. Phylogenetic comparisons also indicate that while MRP1, MRP3, and MRP6 transporters potentially arose from a single transporter in basal deuterostomes, alternative splicing appears to have been the major mode of functional diversification in invertebrates, while duplication may have served a more important role in vertebrates. These results provide a deeper understanding of the evolutionary origins of MRP transporters and the potential mechanisms used to diversify their functions in different groups of animals.

Topics: Alternative Splicing; Animals; Biological Transport; Evolution, Molecular; Exons; Fluoresceins; Fluorescent Dyes; Gene Duplication; Multidrug Resistance-Associated Proteins; Phylogeny; Sea Urchins

Resistance to anticancer drugs has been attributed to an array of cellular changes. The multidrug resistance-related protein (MRP1) is an efflux pump whose overexpression confers resistance to several classes of drugs, such as the anthracyclines, epipodophyllotoxins, and vinca alkaloids. These drugs are mainstays in cancer therapy. MRP1 overexpression is hypothesized to be a causative agent of clinical treatment failure. Consistently accurate methods for detecting this protein are necessary to further understand its biology and delineate its possible clinical relevance. Flow cytometric analysis of multidrug resistance (MDR) is a valuable method to evaluate both antigen expression and function. Using flow cytometry, we assayed MRP1 functional activity in pediatric leukemic blasts and an array of MDR+ and WT cell lines. We conclude that calcein AM, when used in a retention assay with MRP1-specific modulators, is able to reliably detect MRP functional activity. 2'-7'-bis(2-carboxyethyl)-5(6)-carboxyfluorescein (BCECF AM) transport is not indicative of MRP1 overexpression. .

Topics: Child; DNA-Binding Proteins; Drug Resistance, Multiple; Flow Cytometry; Fluoresceins; Humans; Leukemia, Myeloid; Multidrug Resistance-Associated Proteins; MutS Homolog 3 Protein; Tumor Cells, Cultured

Most conventional assays for the in vitro measurement of polymorphonuclear leukocyte (PMN) migration are modifications of the Boyden chamber technique, which requires quantification of migrated cells on micropore filters. This quantification is accompanied by several disadvantages, comprising errors in direct cell counting, low sensitivity of turbidimetric methods, the loss of marker enzymes by activation of PMNs, or the use of radioactive isotopes. We set up an improved fluorometric method to measure chemotactic and haptotactic migration of PMNs using polycarbonate filter-bearing Transwell culture plate inserts. This improved fluorometric method allows the evaluation of effects of fluorescent-dye labeling on chemotaxis and haptotaxis - defined as cell migration due to cell surface- or matrix-bound gradients of chemoattractants - by collecting data in an automated system. Results were compared with data obtained from direct microscopic cell counting in Transwell experiments as well as in conventional 48-multiwell Boyden chamber assays. Calcein-AM and BCECF-AM proved to be fluorochromes with minimal effect on both types of PMN migration. We conclude that the fluorochromes are powerful tools for the analysis of PMN migration and allow modifications of chemotaxis/haptotaxis assays for automated quantification.

Topics: Chemotaxis; Cytological Techniques; Fluoresceins; Fluorescent Dyes; Granulocytes; Humans

Fluorescent probes have been utilized to label leukocytes for both in vivo and in vitro studies of cell migration; however, the effects of such probes on migration have not been determined. The aim of this study was to examine the effects of two commonly used fluorescent probes on leukocyte chemotaxis. J774 macrophages were labeled with either calcein-acetoxymethyl ester (calcein-AM) or 2',7'-bis-(2-carboxyethyl)-5-(and 6)-carboxyfluorescein, acetomethyl ester (BCECF-AM), then assayed for their ability to migrate to zymosan-activated serum (ZAS). Cell migration was quantified by two methods: visual counting of cells and measuring cell fluorescence. Using the cell counts, comparison of unlabeled and fluorescently labeled macrophages demonstrated that BCECF-AM decreased the number of cells responding to ZAS, while calcein-AM had essentially no effect. Neither probe significantly affected the number of cells migrating to medium alone. The inhibitory effects of BCECF-AM on cell migration increased with probe concentration (0.1-1.0 microM) and cell fluorescence. Cell viability was unaffected by either probe. In contrast to the results obtained by visual counting, measuring fluorescence of migrated cells did not reveal a significant difference between the chemotactic response of macrophages labeled with BCECF-AM and those labeled with calcein-AM. These experiments indicated that fluorescent probes can affect the chemotactic response and that inhibitory activity of these probes may not be detected when chemotaxis is quantified solely by automated methods.

Topics: Animals; Cell Count; Cell Line; Cell Movement; Chemotaxis; Flow Cytometry; Fluoresceins; Macrophages; Mice