Staining of mitochondrial membranes with 10-nonyl acridine orange, MitoFluor Green, and MitoTracker Green is affected by mitochondrial membrane potential altering drugs.

BACKGROUND: We set out to develop an assay for the simultaneous analysis of mitochondrial membrane potential and mass using the probes 10-nonyl acridine orange (NAO), MitoFluor Green (MFG), and MitoTracker Green (MTG) in HL60 cells. However, in experiments in which NAO and MFG were combined with orange emitting mitochondrial membrane potential (DeltaPsi(m)) probes, we found clear responses to DeltaPsi(m) altering drugs for both probes. METHODS: The three probes were titrated to determine whether saturation played a role in the response to drugs. The effects of a variety of DeltaPsi(m) altering drugs were tested for MFG and MTG at probe concentrations of 20 nM and 200 nM and for NAO at 0.1 microM and 5 microM, using rhodamine 123 at 0.1 microM as a reference probe. RESULTS: Incubation of GM130, HL60, and U937 cells with 2,3-butanedione monoxime (BDM), nigericin, carbonyl cyanide 3-chlorophenylhydrazone (CCCP), carbonyl cyanide p-(trifluoromethoxy)phenylhydrazone (FCCP), 2,4-dinitrophenol (DNP), gramicidin, ouabain, and valinomycin resulted in increases of the fluorescence intensity for MFG or MTG with only a few exceptions. The fluorescence intensity of cells stained with 0.1 microM NAO increased following incubation with BDM, nigericin, and decreased for FCCP, CCCP, DNP, gramicidin, and valinomycin. The results with 5 microM NAO were similar. CONCLUSIONS: MFG, MTG, and NAO appeared poor choices for the membrane potential independent analysis of mitochondrial membrane mass. Considering the molecular structure of these probes that favor accumulation in the mitochondrial membrane because of a positive charge, our results are not surprising. Cytometry 39:203-210, 2000. Published 2000 Wiley-Liss, Inc.

Simultaneous analysis of relative DNA and glutathione content in viable cells by phase-resolved flow cytometry.

BACKGROUND: Analysis of the DNA cell cycle and glutathione content cannot be performed on viable cells, because the fluorescence emissions of the DNA-specific probe Hoechst 33342 and the glutathione-specific probe monobromobimane overlap completely. We decided to explore whether the emissions could be resolved by the singlet excited state lifetimes of the probes. METHODS: Viable cells were first incubated with Hoechst 33342 at 37 degrees C for 30 min and then with monobromobimane at room temperature for 10 min. Samples were excited with a sinusoidally modulated laser beam (10 MHz) in a flow cytometer. The Hoechst 33342 and monobromobimane lifetimes and fluorescence intensities were resolved by using phase-sensitive detectors. RESULTS: The observed singlet excited state lifetimes were 1.5 ns for Hoechst 33342 and 12 ns for monobromobimane. The glutathione (GSH) content was shown to increase as cells (GM130, HL60, U937) progressed through the cell cycle. However, after the data were corrected for differences in cell volume, it was found that the GSH concentration was constant throughout the cell cycle of the exponentially growing cells. CONCLUSIONS: Phase-resolved flow cytometry provides a means for the specific analysis of the GSH content/concentration as a function of the cell's position in the DNA cell cycle in viable cells.

The mouse Y chromosome: enrichment, sizing, and cloning by bivariate flow cytometry.

In this report, we demonstrate the utility of interleukin-2 (IL-2) stimulation of spleen cell cultures and bivariate flow cytometry in the analysis and purification of the C57BL/6J mouse Y Chromosome. We determined that the DNA content of the C57BL/6J Y Chromosome is approximately 94.7 Mb, making it similar in size to human Chromosome 16 and significantly larger than previous estimates. In addition, we describe the bulk isolation of mouse Y Chromosomes and demonstrate enrichment of the isolated material using a fluorescence in situ hybridization strategy. We detail the construction of two small insert Y Chromosome-specific libraries, ideal for sampling Y Chromosome sequences. From these libraries 1566 clones were analyzed. We provide a detailed characterization of 103 clones, generating nearly 50 kb of sequence. For 30 of these clones, we identify regions of homology to known Y chromosomal sequences, confirming the enrichment of the sorted DNA. From the remaining characterized clones, we describe the development of 15 male-specific PCR assays and 19 male-female PCR assays potentially originating from the pseudoautosomal region or other areas of X-Y or autosome-Y homology.

New flow cytometric technologies for the 21st century.

The envelope that defines the limits within which flow cytometry was developed is being rapidly expanded. For example: detection sensitivity has been extended to single molecules, the size range of "particle" analysis now extends from DNA fragments to plankton (1,000.+ microns), cell and chromosome sorting rates are being increased dramatically by using inactivation procedures (50,000 per second versus 2,000 per second), rapid kinetic flow cytometry enables real-time analysis of molecular assembly and cell function in the sub-second time domain, the lifetime of a fluorochrome bound to a single cell can be measured with nsec precision, and classical karyotype information (cell to cell heterogeneity) can be determined in a flow based system. These frontiers have greatly expanded the range of new and exciting flow cytometric based biomedical applications. New enabling technologies have provided the means to measure DNA cleavage by the structure-specific nuclease, human Flap Endonuclease (FEN-1), in the 300 msec time frame. Phase sensitive measurements and fluorescence lifetime are proving to be major advances for understanding molecular environments that change with, for example, the process of apoptosis. The ability to detect single fluorescent molecules has been applied to the analysis of DNA fragments obtained from enzymatic digestion of lambda DNA. This technology is being used to rapidly and very accurately size DNA fragments for the human genome project. Optical chromosome selection is a faster, better, less complex approach to chromosome sorting. This method is based on the induction of specific damage to the DNA of selected chromosomes. Lastly, the miniaturization of a single cell fractionator has made it possible to perform single cell flow cytogenetics.