Opioid-mediated suppression of cultured peripheral blood mononuclear cell respiratory burst activity.
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Abstract Opiate addiction and stress have been associated with altered immune responses. In this study, we evaluated the influence of morphine and the stress responsive opioid peptide beta-endorphin (beta-END) on O-2 and H2O2 production by cultured human peripheral blood mononuclear cells. Exposure of these cells during 48 hr of culture to morphine and beta-END at pharmacologically (10(-8) M) and physiologically (10(-12) M) relevant concentrations, respectively, markedly suppressed peripheral blood mononuclear cell O-2 and H2O2 release in response to the respiratory burst stimuli opsonized zymosan and phorbol myristate acetate. Both opioids also induced a minimal, but statistically significant, increase in resting O-2 and H2O2 generation. The modulatory effects of morphine and beta-END on peripheral blood mononuclear cell oxygen metabolism appeared to involve a classical opioid receptor, because opioid activity was blocked by naloxone and was not observed with N-acetylated-beta-END. Using purified lymphocyte and monocyte preparations, we determined that although opioids directly increase monocyte-resting oxygen metabolism, lymphocytes are the primary target cell in opioid-mediated suppression of monocyte respiratory burst activity. The release of a suppressive product from opioid-triggered lymphocytes was inhibited by cyclosporine. Based on the results of this study, we propose that opioid-mediated suppression of mononuclear phagocyte respiratory burst activity is another factor to be considered in the immunodeficiency of opiate addiction and stress.Keywords:
Zymosan
Monocyte
Respiratory burst
beta-Endorphin
Zymosan
Respiratory burst
Human blood
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Respiratory burst
Complement
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Zymosan
Respiratory burst
Phorbol
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Respiratory burst
Nitroblue tetrazolium
Formazan
Polymorphonuclear leukocyte
Lucigenin
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To assess the potential effect of an orally administered immunomodulator, consisting of a lysate of seven different bacteria, on polymorphonuclear leukocyte (PMN) function, rabbits were fed this preparation for five consecutive days via a gastric tube. On day 6, PMN were separated from peripheral blood and oxidative burst was triggered by opsonized zymosan or 12-O-tetradecanoylphorbol-13-acetate and quantitated on a single-cell basis. This study presents the extension of an existing flow cytometric method, leading to the possibility of quantitating single-cell oxidative burst triggered by particulate (instead of only soluble) stimuli. By this means, treated animals showed statistically significant increased oxidative burst reactions compared with the control group. The data provide evidence that oral application of a bacterial immunomodulator leads to a primed state in PMN for increased oxidative activity in response to a particulate stimulus. This offers the possibility that the beneficial effect of similar treatment in humans may in part be due to comparable mechanisms.
Zymosan
Respiratory burst
Phagocytic Cell
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Macrophages isolated from normal mucosa (greater than 5 cm from tumour) and inflamed mucosa (from patients with inflammatory bowel disease) of colon and ileum were studied for their ability to undergo a respiratory burst as assessed by reduction of nitroblue tetrazolium to formazan. Using phorbol myristate acetate (PMA) and opsonised zymosan as triggers, only a minority (median: 8% for zymosan and 9% for PMA) of macrophages isolated from normal colonic mucosa demonstrated release of oxygen radicals. In contrast, a significantly greater (median: 17% for zymosan and 45% for PMA) proportion of macrophages isolated from inflamed colonic mucosa were able to undergo respiratory burst. Studies with normal and inflamed ileum showed similar results. Stimulation of macrophages isolated from normal colon with interferon-gamma produced only a small increase in the proportion of cells showing release of oxygen radicals. We conclude that the respiratory burst capacity of majority of macrophages isolated from normal colon and ileum is downregulated and a greater proportion of macrophages isolated from inflamed colon and ileum are able to undergo a respiratory burst.
Zymosan
Respiratory burst
Intestinal mucosa
Phorbol
Respiratory Mucosa
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Mature polymorphonuclear neutrophilic leukocytes (PMNL)from a 2.5-year-old female with infantile chronic myelogenous leukemia (CML) were stimulated with phorbol myristate acetate or opsonized zymosan. The resulting enzymatic NADPH oxidation and the cellular O2− release and luminol-enhanced chemiluminescence were measured. The patient's PMNL responded normally in all respects. Thus, mature infantile CML PMNL undergo a normal respiratory burst following either soluble or particulate stimulation. Our review of the literature emphasizes the importance of studying a well-defined population of PMNL in patients with myelodysplasia.
Zymosan
Respiratory burst
Chronic myelogenous leukemia
Chronic Granulomatous Disease
Philadelphia chromosome
Neutrophil elastase
Blast Crisis
Phorbol
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Plasma fibronectin (FN) has been demonstrated to serve as an opsonin involved in the ingestion of foreign particles by phagocytes. This study concerns the effect of FN exposure on the respiratory burst of normal human peripheral phagocytes, using a luminol-dependent chemiluminescence (CL) assay for measurement of reactive oxygen metabolites generated. FN enhanced, in a dose-dependent manner, the CL response of circulating monocytes stimulated, probably via beta-glucan receptor, with unopsonized zymosan. FN also increased the CL response of phagocytes to fresh serum-opsonized zymosan. When we used a glycolipid (ceramide pentasaccharide, CPS) incorporated on liposome membranes as an antigen, the immune complexes prepared between CPS and human IgG (as antibody) did not induce a CL response, differing from previous reports. Addition of FN to the immune complexes significantly enhanced the CL response of phagocytes. The role of FN in host defence is discussed.
Zymosan
Respiratory burst
Phagocyte
Antibody opsonization
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Recent evidence has suggested that a particulate O(2) (-)-forming system is responsible for the respiratory burst in activated neutrophils. The respiratory burst is normally a transient event, lasting only 30-60 min. To investigate the mechanism by which the burst is terminated, we examined the O(2) (-)-forming activity of neutrophil particles as a function of time in the presence and absence of agents known to affect the function of intact cells. Measurements of the O(2) (-)-forming capacity of the particles against time of exposure of neutrophils to opsonized zymosan, a potent stimulating agent, revealed a rapid fall in activity when exposure was continued beyond 3 min. Exposure to zymosan under conditions in which the myeloperoxidase system was inactive (i.e., in the presence of myeloperoxidase inhibitors, or in the absence of oxygen) resulted in a substantial increase in the initial O(2) (-)-forming activity of particles from the zymosan-treated cells, but did not prevent the sharp fall in activity seen when zymosan exposure exceeded 10 min. The fall in activity was, however, prevented when activation took place in the presence of cytochalasin B (1.5 mug/ml), an agent thought to act largely by paralyzing the neutrophil through an interaction with its microfilament network.We conclude from these findings that the termination of the respiratory burst results at least in part from the inactivation of the particulate O(2) (-)-forming system. This inactivation involves at least two processes which probably act simultaneously. One is the destruction of the system through the action of myeloperoxidase. The other appears to require active cell motility and is independent of oxygen. The current view holds that the O(2) (-)-forming system of the neutrophil is located in the plasma membrane. It may be that the second process involves the internalization and degradation of this membrane-bound system.
Zymosan
Respiratory burst
Cytochalasin B
Cytochalasin
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