Abstract
The aim of the present study was to detect oxidant-producing sites, and to elucidate their dynamic reorganization in human polymorphonuclear leukocytes (PMNs) fixed with glutaraldehyde which preserves cell structure. In biochemical analyses, the detectable O2− generation in unfixed PMNs upon stimulation with phorbol 12-myristate 13-acetate (PMA) in the presence of cytochalasin B was characterized by a lag period of approximately 10 sec followed by O2− production. The maximal rate reached was 3.18±0.07 n mol/min/1×106 cells (mean±S.D.; n=4) after 30 sec of stimulation. PMNs exposed to PMA and cytochalasin B followed by fixation with glutaraldehyde generated O2− without a lag period at a rate of 0.35±0.05 n mol/min/1×106 cells (mean±S.D.) by the addition of NADPH as substrate to the cell suspension. In the cytochemical assays, we employed both cells exposed to PMA and cytochalasin B, and then fixed with glutaraldehyde followed by incubation in the cytochemical reaction medium (pre-fixed cells) and cells incubated in the medium containing PMA and cytochalasin B followed by fixation with glutaraldehyde (post-fixed cells). Oxidant reaction in the pre-fixed cells was detected by the addition of NADPH and FAD to the reaction medium. No oxidant-reaction product was seen in pre-fixed cells stimulated for 10 sec whereas the oxidant reaction was visualized in intracellular compartments of pre-fixed PMNs stimulated for 20 sec. The fact that the pre-fixed PMNs stimulated for 30 sec showed increased numbers of oxidant-producing structures compared to those seen in the pre-fixed cells stimulated for 20 sec, demonstrates that the amount of the reaction product and the number of oxidant-producing intracellular compartments increases between 20 and 30 sec after start of stimulation with PMA. These cytochemical results using the pre-fixed cells coincided with the findings obtained from the biochemical assays in the pre-fixed cells exposed to PMA and cytochalasin B. The oxidant reaction was observed in elongated tubular structures that were arranged in a radial fashion, and were associated with the plasma membrane in the pre-fixed PMNs, whereas post-fixed PMNs exhibited slender spherical or rod-shaped structures of various lengths. The present results indicate that the pre-fixed PMNs can be employed for elucidating the dynamic reorganization of oxidant-producing sites in human PMNs.
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Kobayashi, T., Garcia del Saz, E., Hendry, J. et al. Detection of Oxidant Producing-sites in Glutaraldehyde-fixed Human Neutrophils and Eosinophils Stimulated with Phorbol Myristate Acetate. Histochem J 31, 181–194 (1999). https://doi.org/10.1023/A:1003547121574
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DOI: https://doi.org/10.1023/A:1003547121574