Eosinophils, which may be associated with allergic, parasitic, or neoplastic disease, have a potent oxidative burst that may be activated by particulate or soluble stimuli. Eosinophils from normal persons and patients with hypereosinophilia were compared with respect to their ability to produce the active oxygen product, superoxide anion. Normal eosinophils produced large amounts of superoxide anion under resting conditions (0.53 +/- 0.15 nmoles cyto-c/10(5) eos/hr) and when stimulated by preopsonized zymosan (0.85 +/0 1.10 nmoles cyto-c/10(5) eos/hr) or phorbol myristate acetate (PMA) (2.38 +/- 0.46 nmoles cyto- c/10(5) eos/hr). Considerable variation was observed in superoxide production by eosinophils from patients with hypereosinophilia. Eosinophils from a group of four patients with hypereosinophilia associated with neoplastic disease produced less superoxide anion than normal eosinophils when stimulated by preopsonized zymosan or PMA (p less than or equal to 0.05). Eosinophils from a group of 5 patients with other causes of hypereosinophilia produced more superoxide anion than normal eosinophils when stimulated by PMA (p less than or equal to 0.01). These studies demonstrate metabolic heterogeneity of eosinophils from patients with hypereosinophilia, and further emphasize that normal eosinophils and eosinophils from hypereosinophilic patients are not functionally equivalent.
Eosinophils, which may be associated with allergic, parasitic, or neoplastic disease, have a potent oxidative burst that may be activated by particulate or soluble stimuli. Eosinophils from normal persons and patients with hypereosinophilia were compared with respect to their ability to produce the active oxygen product, superoxide anion. Normal eosinophils produced large amounts of superoxide anion under resting conditions (0.53 +/- 0.15 nmoles cyto-c/10(5) eos/hr) and when stimulated by preopsonized zymosan (0.85 +/0 1.10 nmoles cyto-c/10(5) eos/hr) or phorbol myristate acetate (PMA) (2.38 +/- 0.46 nmoles cyto- c/10(5) eos/hr). Considerable variation was observed in superoxide production by eosinophils from patients with hypereosinophilia. Eosinophils from a group of four patients with hypereosinophilia associated with neoplastic disease produced less superoxide anion than normal eosinophils when stimulated by preopsonized zymosan or PMA (p less than or equal to 0.05). Eosinophils from a group of 5 patients with other causes of hypereosinophilia produced more superoxide anion than normal eosinophils when stimulated by PMA (p less than or equal to 0.01). These studies demonstrate metabolic heterogeneity of eosinophils from patients with hypereosinophilia, and further emphasize that normal eosinophils and eosinophils from hypereosinophilic patients are not functionally equivalent.
A protocol for the purification of carp eosinophils on metrizamide gradients is presented. Density gradient centrifugation is a new approach to the study of eosinophils in fish. It provides enriched populations of viable eosinophils necessary for in vitro functional assays. Eosinophils purified from the peripheral blood of carp resemble mammalian eosinophils by light and electron microscopy. They are indistinguishable from carp neutrophils which have a different density and morphology.
Approximately half of the colony-forming units-culture (CFU-C) from normal peripheral blood are eosinophilic. The purpose of our study was to determine: (1) whether progenitor cells committed to eosinophil or neutrophil maturation would be differentially affected by feedback inhibition, and (2) whether mature eosinophils added to the feeder layers of the culture would inhibit the proliferation of CFU-C in a manner similar to that described for neutrophils. Concentrated eosinophils and neutrophils, obtained by separation on a metrizamide gradient, were added to feeder layers containing either 10(6) autologous whole mononuclear cells (WMNC) or 0.1 ml of leukocyte conditioned media (LCM). The average number of colonies was 123/10(6) nonadherent cells (NAC) cultured. When neutrophils or eosinophils were added to the WMNC feeder layer, the percent inhibition of growth was 40.2% +/- 1.6% (mean +/- SEM) and 42.3% +/- 5.4%, respectively, but the ratio of neutrophil to eosinophil colonies remained constant. No effect was seen when neutrophils or eosinophils were added to an LCM feeder layer. Thus, it appears that the differential control of neutrophil versus eosinophil production in vitro is not regulated through feedback inhibition by mature granulocytes. In addition, these studies suggest that eosinophils, as well as neutrophils, cause inhibition of CFU-C growth when intact cells are the source of colony-stimulating factor (CSF).
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