Robert J. Bonney

Macrophages synthesise and release prostaglandins in response to inflammatory stimuli

WHEN macrophages encounter inflammatory stimuli either in vivo or in vitro, they respond by releasing a number of products which may account for the central role that this cell has in chronic inflammatory diseases1. These products include hydrolytic enzymes active at neutral2 or acidic pH (ref. 1), components of both the classical3 and alternate pathway4 of complement, factors modulating responses of lymphocytes to antigens and mitogens5, and factor(s) influencing the proliferation6 and synthesis of collagen7 by fibroblasts. We now show that macrophages whose phospholipid components were labelled with 3H-arachidonic acid also synthesise and release 3H-prostaglandins (PGs) in response to inflammatory stimuli. These observations are consistent with the findings that human macrophages on intrauterine devices8 and guinea pig macrophages responding to lymphokines9 release PGs.

Physiological and pharmacological regulation of prostaglandin and leukotriene production by macrophages

The synthesis and secretion of prostaglandins and leukotrienes by mouse peritioneal macrophages is under several regulatory controls. Arachidonic acid must first be released from phospholipid stores by the action of phospholipases. Macrophages have the capacity to deacylate arachidonic acid directly from the SN2 position of phospholipids via the action of a phospholipase A2. In addition, these cells contain a phospholipase C capable of removing inositolphosphate from phosphatidylinositol generating diacylglycerol. Another enzyme, diacylglycerol lipase is present to then generate arachidonic acid. The free arachidonic acid then enters the cyclooxygenase pathway to generate prostaglandins, the lipoxygenase pathway to generate leukotrienes or both pathways. The nature of the inflammatory stimulus added to these cells determines which of the above pathways become operative. Zymosan and the Ca+ + ionophore, A23187 stimulate the synthesis of both prostaglandins and leukotrienes whereas phorbol myristate acetate and lipopolysaccharide induce only the synthesis of prostaglandins. In addition, the synthesis of these two products by macrophages can be regulated by certain antiinflammatory compounds. Indomethacin, aspirin, ibuprofen and benoxaprofen are only inhibitors of the prostaglandin pathway, whereas BW755C, 5,8,11 ETYA, NDGA and sulindac sulfide (high doses) are inhibitors of the synthesis of both prostaglandins and leukotrienes. Dapsone, an effective drug for leprosy, also inhibits the synthesis of both of these products.

Antigen-antibody complexes stimulate the synthesis and release of prostaglandins by mouse peritoneal macrophages.

Antigen-antibody complexes (Ag/Ab) formed at equivalence stimulate the release of arachidonic acid and synthesis of prostaglandin E2 and 6-keto-prostaglandin F1 alpha by resident mouse peritoneal macrophages. Prostaglandin synthesis and secretion is stimulated by submicrogram quantities of Ag/Ab which increases in a dose-dependent manner. This release is time-dependent and occurs in the absence of any loss of cell viability as indicated by increased cellular levels of lactate dehydrogenase without concomitant loss of this activity to the media and the continued secretion of a constitutive cellular product, lysozyme. The stimulated synthesis of prostaglandins by Ag/Ab is inhibited by indomethacin and physiological levels of antiinflammatory glucocorticoids.

Pharmacological effects of non-steroidal antiinflammatory agents on prostaglandin and leukotriene synthesis in mouse peritoneal macrophages

Resident mouse peritoneal macrophages, exposed to zymosan, synthesized and released products of both the cyclooxygenase and lipoxygenase pathways. The effects of various non-steroidal antiinflammatory agents were evaluated for their abilities to inhibit zymosan-stimulated prostaglandin E2 (PGE2) and leukotriene C4 (LTC4) synthesis. The order of potencies to inhibit PGE2 synthesis and release was: indomethacin greater than or equal to sulindac sulfide greater than ibuprofen greater than or equal to aspirin greater than 3-amino-1-[3-(trifluoromethyl)-phenyl]-2-pyrazoline (BW755C) greater than benoxaprofen greater than or equal to nordihydroguaiaretic acid (NDGA) greater than 5,8,11-eicosatriynoic acid (ETYA). BW755C and ETYA also inhibited zymosan-stimulated LTC4 production. None of the compounds tested showed selective inhibition of lipoxygenase products.

Effect of RNA and protein synthesis inhibitors on the release of inflammatory mediators by macrophages responding to phorbol myristate acetate

The interaction of phorbol myristate acetate with resident populations of mouse peritoneal macrophages causes an increased release of arachidonic acid followed by increased synthesis and secretion of prostaglandin E2 and 6-keto-prostaglandin F1 alpha. In addition, phorbol myristate acetate causes the selective release of lysosomal acid hydrolases from resident and elicited macrophages. These effects of phorbol myristate acetate on macrophages do not cause lactate dehydrogenase to leak into the culture media. The phorbol myristate acetate-induced release of arachidonic acid and increased synthesis and secretion of prostaglandins by macrophages can be inhibited by RNA and protein synthesis inhibitors, whereas the release of lysosomal hydrolases is unaffected. 0.1 microgram/ml actinomycin D blocked the increased prostaglandin production due to this inflammatory agent by more than 80%, and 3 microgram/ml cycloheximide blocked prostaglandin production by 78%. Similar results with these metabolic inhibitors were found with another stimulator of prostaglandin production, zymosan. However, these inhibitors do not interfere with lysosomal hydrolase releases caused by zymosan or phorbol myristate acetate. It appears that one of the results of the interaction of macrophages with inflammatory stimuli is the synthesis of a rapidly turning-over protein which regulates the production of prostaglandins. It is also clear that the secretion of prostaglandins and lysosomal hydrolases are independently regulated.

Lysosomotropic Agents II. Synthesis and Cytotoxic Action of Lysosomotropic Detergents

Amines whose pK values lie between about 5 and 9 are lysosomotropic because lysosomes are acidic intracellular compartments. If such amines bear long hydrophobic chains, they become detergents upon protonation inside the lysosomes, rupturing the lysosomal membrane and killing the cell. Six types of lysosomotropic amines have been prepared that all behave in the expected manner. They are cytotoxic to all lysosome-bearing cells but not red blood cells, which lack lysosomes. Their mode of action, the effect of alkyl chain length on activity, and the fact that their cytotoxic action appears only above a threshhold intracellular concentration support the belief that they behave as lysosomotropic detergents. Among the potential applications is cancer chemotherapy.

Role of leukocyte factors and cationic polyelectrolytes in phagocytosis of group A streptococci and Candida albicans by neutrophils, macrophages, fibroblasts and epithelial cells: modulation by anionic polyelectrolytes in relation to pathogenesis of chronic inflammation.

A variety of cationic polyelectrolytes opsonized group A streptococci andCandida albicans to phagocytosis by human polymorphonuclear leukocytes and by mouse peritoneal macrophages. The most potent opsonins for streptococci were specific antibodies supplemented with complement, nuclear histone, polylysine, polyarginine, ribonuclease, leukocyte lysates, leukocyte cationic protein and, to a lesser extent, lysozyme and myeloperoxidase. Histone, RNAse, leukocyte extracts, and platelet extracts also functioned as opsonins for phagocytosis of streptococci in the peritoneal cavity, where phagocytic indices, higher than those obtained for the in vitro phagocytosis, were obtained. Fresh serum, polylysine, polyarginine, and nuclear histone acted as good opsonins forCandida, but none of the other factors tested were active. In order for the cationic proteins and leukocyte extracts to function as opsonins, they must be present on the particle surface. These agents were poor opsonins when applied on the macrophages. Nuclear histone, polylysine, polyarginine, and fresh human serum also functioned as good opsonins for the uptake ofCandida by mouse fibroblasts. On the other hand, none of the other substances which opsonized streptococci were effective withCandida. The phagocytic capabilities of fibroblast polykaryons were much higher than those of ordinary spindle-shaped mouse fibroblasts. Histone also functioned as a good opsonic agent for the uptake ofCandida by human fibroblasts, HeLa cells, epithelial cells, monkey kidney cells, and rat heart cells. On the other hand, neither leukocyte extracts nor ribonuclease LCP or MPO functioned as opsonins for these mammalian cells.Candida, taken up by fibroblasts, were present within tight phagosomes, but no fusion of lysosomes with the phagosome occurred. A small proportion of the internalized yeast cells underwent partial plasmolysis, but little damage to the rigid cell walls was observed within 24–48 h of internalization. Phagocytosis of streptococci andCandida by macrophages and the uptake ofCandida by fibroblasts were both strongly inhibited by liquoid (polyanethole sulfonic acid sodium salt). This anionic polyelectrolyte also markedly inhibited the release ofN-acetylglucosaminidase from macrophages without affecting cell viability (LDH release). Hyaluronic acid, DNA, and dextran sulfate markedly inhibited the uptake of histone-coated particles by macrophages. On the other hand, hyaluronic acid and DNA enhanced the uptake ofCandida by fibroblasts. The effect of these anionic polyelectrolytes on phagocytosis of serum-opsonized particles by macrophages was not consistent. While in some experiments it blocked phagocytosis, in others it either had no effect or even enhanced the uptake of the particles. Phagocytosis of microorganisms by “nonprofessional” phagocytes like fibroblasts and the paucity in these cells of hydrolases capable of breaking down microbial cell wall components may contribute to the persistence of non-biodegradable components of bacteria in tissues and to the perpetuation of chronic inflammatory sequellae. Cationic polyelectrolytes may also prove important as “helper” opsonins and as agents capable of enhancing the penetration into cells of both viable and nonviable particles, genetic material, and drugs.A variety of cationic polyelectrolytes opsonized group A streptococci andCandida albicans to phagocytosis by human polymorphonuclear leukocytes and by mouse peritoneal macrophages. The most potent opsonins for streptococci were specific antibodies supplemented with complement, nuclear histone, polylysine, polyarginine, ribonuclease, leukocyte lysates, leukocyte cationic protein and, to a lesser extent, lysozyme and myeloperoxidase. Histone, RNAse, leukocyte extracts, and platelet extracts also functioned as opsonins for phagocytosis of streptococci in the peritoneal cavity, where phagocytic indices, higher than those obtained for the in vitro phagocytosis, were obtained. Fresh serum, polylysine, polyarginine, and nuclear histone acted as good opsonins forCandida, but none of the other factors tested were active. In order for the cationic proteins and leukocyte extracts to function as opsonins, they must be present on the particle surface. These agents were poor opsonins when applied on the macrophages. Nuclear histone, polylysine, polyarginine, and fresh human serum also functioned as good opsonins for the uptake ofCandida by mouse fibroblasts. On the other hand, none of the other substances which opsonized streptococci were effective withCandida. The phagocytic capabilities of fibroblast polykaryons were much higher than those of ordinary spindle-shaped mouse fibroblasts. Histone also functioned as a good opsonic agent for the uptake ofCandida by human fibroblasts, HeLa cells, epithelial cells, monkey kidney cells, and rat heart cells. On the other hand, neither leukocyte extracts nor ribonuclease LCP or MPO functioned as opsonins for these mammalian cells.Candida, taken up by fibroblasts, were present within tight phagosomes, but no fusion of lysosomes with the phagosome occurred. A small proportion of the internalized yeast cells underwent partial plasmolysis, but little damage to the rigid cell walls was observed within 24–48 h of internalization. Phagocytosis of streptococci andCandida by macrophages and the uptake ofCandida by fibroblasts were both strongly inhibited by liquoid (polyanethole sulfonic acid sodium salt). This anionic polyelectrolyte also markedly inhibited the release ofN-acetylglucosaminidase from macrophages without affecting cell viability (LDH release). Hyaluronic acid, DNA, and dextran sulfate markedly inhibited the uptake of histone-coated particles by macrophages. On the other hand, hyaluronic acid and DNA enhanced the uptake ofCandida by fibroblasts. The effect of these anionic polyelectrolytes on phagocytosis of serum-opsonized particles by macrophages was not consistent. While in some experiments it blocked phagocytosis, in others it either had no effect or even enhanced the uptake of the particles. Phagocytosis of microorganisms by “nonprofessional” phagocytes like fibroblasts and the paucity in these cells of hydrolases capable of breaking down microbial cell wall components may contribute to the persistence of non-biodegradable components of bacteria in tissues and to the perpetuation of chronic inflammatory sequellae. Cationic polyelectrolytes may also prove important as “helper” opsonins and as agents capable of enhancing the penetration into cells of both viable and nonviable particles, genetic material, and drugs.

Extended expression of differentiated function in primary cultures of adult liver parenchymal cells maintained on nitrocellulose filters. I. Induction of phosphoenolpyruvate carboxykinase and tyrosine aminotransferase.

Abstract A new support system has been developed which provides long-term maintenance of non-dividing adult rat liver parenchymal cells in monolayer cultures. The hepatocytes, attached to Millipore (MP) filters, are maintained as free-floating cultures which express differentiated liver cell functions for up to 13 days. After 8 days of culture on MP filters, the hepatocytes are still capable of inducing tyrosine aminotransferase 3- to 4-fold and phosphoenolpyruvate carboxykinase 10-to 15-fold. The advantage of using floating MP filters to support the hepatocytes over the more conventional culture supports such as glass or plastic dishes are: (1) the functional lifespan of cultured hepatocytes is doubled, permitting experiments requiring 4–8 days to complete; (2) it permits rapid and easy transfer of cells from one set of culture conditions to another; (3) sections can be cut from one filter permitting multiple samples from a single culture; (4) the filters containing the cells can be processed without losing the orientation of cell surfaces, an important consideration when employing techniques such as autoradiography and/or electron microscopy; and (5) this culture technique can readily be adapted for co-cultivation experiments in order to directly examine biological and biochemical effects of secreted products of one cell type on another.

Possible Autoregulatory Functions of the Secretory Products of Mononuclear Phagocytes

The ability of mononuclear phagocytes to recognize, ingest, and either digest or remove through various portals of exit from the body a wide variety of infectious agents and toxic materials has been recognized since the seminal observations of Metchnikoff. Mononuclear phagocytes have specialized recognition mechanisms that facilitate these functions, which include (1) several classes of Fc receptors for immune complexes; (2) responsiveness to lymphokines, which serve to enhance their phagocytic and cidal functions; and (3) receptors for complement components, which are either chemotactic or facilitate phagocytosis. During the past decade it became clear that these activities, concerned primarily with the removal of noxious stimuli from the host environment, are accompanied by other specialized functions that have far-reaching effects on the cells and connective tissues present in the pericellular environment of the mononuclear phagocyte. One of these, the ability to present antigenic determinants of ingested materials to cells of the immune system in an immunogenic form (for review, see Rosenthal, 1980), is not discussed here. The other, the ability of mononuclear phagocytes to secrete a diverse range of products, preoccupied many investigators during the past decade.

Phorbol myristate acetate induces the secretion of an elastase by populations of resident and elicited mouse peritoneal macrophages

Cultured thioglycollate-elicited mouse peritoneal macrophages secrete an enzyme which hydrolyzes [3H]elastin prepared by NaB3H4 reduction of bovine ligamentum nuchae elastin. Over a 24 h culture period, 3.5 . 10(6) thioglycollate-elicited cells secrete sufficient enzyme to solubilize 200--350 micrograms [3H]elastin in 18h. Secretion at this rate continues for at least 6 days in culture. Secretion of the enzyme is stimulated 3-fold by exposure of the cultured cells to 10(-7) M phorbol myristate acetate, whereas the parent alcohol 4 alpha-phorbol is inactive in this respect. Enzyme activity is linearly related to the amount of conditioned medium assayed and is linear over incubation times up to 30 h. Unlabelled elastin competitively inhibits the solubilization of [3H]elastin. The solubilization rate is doubled if the substrate is pretreated with sodium dodecyl sulfate, but the rate of solubilization of this pretreated substrate increases with time. Resident peritoneal macrophages secrete barely detectable amounts of elastase, but phorbol myristate acetate (10(-7) M) stimulates its secretion in amounts comparable to those secreted by phorbol myristate acetate-stimulated thioglycollate-elicited cells. Dexamethasone (10(-9) M) inhibits phorbol myristate acetate-induced secretion by 50%, but 10(-6) M indomethacin is without effect. The secreted enzyme has the characteristics of a metalloproteinase.