Flow Cytometric Measurement of Reactive Oxygen Species to Assess the Effects of Preconditioning Total Body Irradiation on NOG Mice.

BACKGROUND: Preclinical development of new drugs for cancer immunotherapy requires preconditioning total body irradiation (TBI) of mice to be humanized via hematopoietic stem cell transplantation. To assess the effect of preconditioning TBI, we detected the reactive oxygen species (ROS), Annexin V, propidium iodide (PI) level in bone marrow samples by flow cytometer. METHODS: We divided all NOG mice between irradiated (n = 20) and control groups (n = 10) for two time points. Irradiated mice were exposed to 3.5 Gy of radiation. After sacrificing BM samples were collected, the flow cytometric percentage of ROS, Annexin V, and PI markers were investigated on days 2 and 14 after exposure. RESULTS: At the first time point, the level of ROS was higher in the irradiated group than in the control group, and this difference was statistically significant (P < 0.05). Also, at the second time point, the mean differences of all markers in the irradiated group were significantly compared to the control group (P < 0.05). CONCLUSION: Thus, in NOG mice, the measurement of ROS level is helpful to the assessment of preconditioning TBI.

Donor fluorescence decay analysis for energy transfer in double-helical DNA with various acceptor concentrations.

We studied fluorescence resonance energy transfer between donors and acceptors bound to double-helical DNA. The donor Hoechst 33258 binds to the minor groove of DNA and the acceptor propidium iodide (PI) is an intercalator. The time-resolved donor decays were measured in the frequency domain. The donor decays were consistent with a random 1-dimensional distribution of acceptors. The decays were analyzed in terms of three 1-dimensional models: a random continuous acceptor distribution; acceptors placed on discrete lattice sites; and a cylindrical model with the acceptor in the center, and the donors on a cylinder surface. The data were well described by all three models. Interpretation in terms of continuous distribution of acceptors revealed a minimum donor to acceptor distance of 13 A, which is 3 bp from the center of Hoechst 33252. These results suggest that PI is excluded from the 4 bp covered by Hoechst 33252 when it is bound to the minor groove of DNA.

Electron microscopic analysis of fluorescent neuronal labeling after photoconversion.

Ultrastructural visualization of non-electron-dense fluorescent retrograde neuronal labeling was attempted by means of photo-oxidation. This procedure was used to convert the fluorescence of neurons labeled by the tracers propidium iodide, rhodamine latex microspheres and fluorogold into a stable diaminobenzidine reaction product. The ultrastructural study revealed an accumulation of electron-dense material in these cells both within lysosomes and scattered in the cytoplasmic matrix. Comparison with several different sets of control samples indicated that this material, on the basis of its amount, electron density and appearance, specifically represents the photoconversion reaction product. The effects of the intensity of the fluorescent labeling and of a prolonged photoconversion on the fine structural features of the reaction product are also described and discussed. The present findings indicate that photoconversion can be effectively applied to ultrastructural study of fluorescent retrogradely labeled neurons. The specificity of the photoconversion reaction product should be tested routinely for each fluorochrome and tissue sample.

Photo-bleaching and photon saturation in flow cytometry.

In flow cytometry, small particles travel at a high speed through a bright light spot. The high light intensity at the point of measurement causes measurable photon saturation. This observation indicates that the rate at which individual dye molecules emit photons is close to the maximum emission rate. Despite the short exposure time, individual molecules may go through a few hundred excitation cycles while they are in the light beam. The absorbed light dose causes significant dye destruction. This article presents experimental procedures to determine the extent of photon saturation and photo-bleaching of dyes bound to cell nuclei in a flow cytometer. Measurements of Hoechst and propidium iodide bound to chromatin show that the amount of dye bleached per emitted photon is the same at low and high illumination intensities. This finding indicates that photon emission and dye destruction are both the result of the absorption of single excitation photons. The experimental observations allow rough estimates of the lifetime of the excited state and the lifetime of the molecule. The lifetime of the Hoechst 33258 bound to DNA is estimated to be 100 excitation-relaxation cycles. The average propidium iodide molecule lasts approximately 200 excitation-relaxation cycles. The theoretical considerations show that the optimal illumination conditions are different for bleaching and nonbleaching dyes. An optical arrangement for high precision measurements of bleaching dyes is presented.