Establishment of heteroploid cell lines from mouse peritoneal exudate cells.

Proliferation was observed during in vitro cultivation of peritoneal exudate cells that had been educed from a C3H mouse with Freund's incomplete adjuvant. These cells were successfully subcultured by release with trypsin-EDTA solution and are now at passage 108 after 22 months in culture. Using this technique, 12 other rapidly growing peritoneal exudate cultures were obtained, whereas 10 cultures not educed with adjuvant did not proliferate. Characteristics of four adjuvant-induced cell lines established in culture include: rapid attachment to glass, doubling time in culture of 18 to 19 hr, phagocytosis of colloidal carbon, enhanced phagocytosis of specifically sensitized bacteria, epithelium-like morphology, and retention of C3H histocompatible specificities. These cell lines had widely varying chromosome distributions with modes from 37.3 +/- 2.4 to 82.6 +/- 2.30, but inoculation of 10(7) cultured cells into syngeneic animals did not produce tumors. Procedures described for the reproducible establishment of peritoneal exudate cell lines did not require use of conditioned media or exogenous viral infection.     

Inhibition of the mixed lymphocyte culture by peritoneal exudate cells.

Inhibition of mixed lymphocyte cultures (MLC) by macrophages and by supernatants of short term cultured macrophages was assessed by incorporation of ³H-thymidine (TdRH3) and also by blast cell counts and by determination of cellmediated lympholysis. Peritoneal exudate cells (PEC) induced by thioglycollate, at concentrations >10%, inhibited all three parameters of MLC. Lower concentrations of PEC, and supernatants from cultured PEC, inhibited TdRH3 incorporation, but had no significant effect on blast cell counts or on generation of cytotoxic effector cells. Inhibition by the supernatants could be reversed by dialysis or by use of low specific activity TdRH3. These data indicate that macrophages can inhibit proliferative responses in MLC, but that this must be carefully distinguished from selective inhibition of TdRH3 incorporation.     

Sodium-dependent and inhibitor-insensitive uptake of adenosine by mouse peritoneal exudate cells

[8-3H]Adenosine uptake in mouse peritoneal exudate cells, harvested following i.p. challenge with Complete Freund's Adjuvant from BALB/c mice, was found to be insensitive to common nucleoside transport inhibitors such as dilazep or 6-[(4-nitrobenzyl)mercapto]purine ribonucleoside and to require sodium ion, being inactive when sodium was replaced by lithium or potassium. These findings also applied to the adherent (macrophages) and nonadherent (polymorphonuclear cells) cell fractions prepared from the peritoneal cell mixture. Uptake was inhibited by several nucleosides including deoxyadenosine, inosine, uridine, thymidine and, to a lesser extent, by the adenosine analog tubercidin, while adenine, fructose, glucose and ribose were without effect. Uptake [8-3H]adenosine was fully matched by rapid intracellular phosphorylation to AMP, ADP and ATP. Inosine was a substrate for the transporter, but tubercidin was not. The system clearly is distinct from carrier-mediated, nonconcentrative transport and has similarities to concentrative, sodium-dependent nucleoside transporters described in other cell types.     

Characterization of leukotriene C4 synthetase in mouse peritoneal exudate cells

Cell lysates of mouse peritoneal macrophages, in the presence of reduced glutathione, converted leukotriene LTA4 to LTC4, and neither LTD4 nor LTE4 was detected. Therefore, like cultured rat basophilic leukemia cells (RBL cells), the peritoneal macrophage contains LTC4 synthetase and appears to contain little, if any, gamma-glutamyl transpeptidase. When LTA4 was added to subcellular fractions of mouse macrophage lysate, the highest specific activity of LTC4 synthetase (nmol LTC4/mg protein per 10 min) was associated with the particulate or membrane fractions (i.e., 10(4) and 10(5) X g pellets). The 10(5) X g supernatant contains approx. 1% of the specific activity and 6% of the total LTC4 synthetase activity compared with that of the 10(5) X g pellet. Conversely, the 10(5) X g supernatant had four-times more specific activity and 19-times more total GSH S-transferase activity than did the 10(5) X g pellet when evaluated using 1-chloro-2,4-dinitrobenzene (DNCB) as the substrate. LTA4 was converted to LTC4 by the membrane enzyme LTC4 synthetase in a dose-dependent manner at low LTA4 concentrations (3-50 microM) and reached a plateau of approx. 30 microM LTA4 using the macrophage 10(5) X g pellet as an enzyme source. The apparent Km value of LTC4 synthetase for LTA4 was estimated to be 5 microM based on Lineweaver-Burk plots. Enzyme in the 10(5) X g supernatant produced negligible quantities of LTC4 (1% or less of the particulate fractions) over a wide range of LTA4 concentrations. However, an enzyme in the 10(5) X g supernatant fraction presumed to be GSH S-transferase effectively catalyzes the conjugation of glutathione (GSH) with the aromatic compound DNCB. The apparent Km value of GSH S-transferase for DNCB was estimated to be 1.0-1.5 mM. On the other hand, enzyme from the membrane fraction (i.e., 10(5) X g pellet) catalyzed this reaction at a negligible rate over a wide range of DNCB concentrations. The apparent Km value of LTC4 synthetase for GSH was estimated to be 0.36 mM and the corresponding Km value estimated for the glutathione S-transferase was 0.25-0.76 mM. These values indicate similar kinetics for GSH utilization by both enzymes. These Km values are also significantly lower than the intracellular GSH levels of 2 to 5 mM. Therefore, it is suggested that the substrate limiting LTC4 synthetase activity is LTA4 and not GSH. Our results indicate that LTC4 synthetase from mouse peritoneal macrophages is a particulate or membrane-bound enzyme, as was reported by Bach et al.(ABSTRACT TRUNCATED AT 400 WORDS)     

Phagocytosis of Protamine—heparin aggregates by mouse peritoneal exudate cells

Protamine--heparin aggregates (PHAg's) were injected intraperitoneally into thioglycollate-prestimulated mice, peritoneal exudate cells, chiefly macrophages (M phi's) being collected after 2, 15 and 60 min, 6 h, and 30 h for electron microscopy and histochemistry. An intensive phagocytosis of PHAg's was seen even after 5 min and extracellular spaces were cleared of them after 60 min. The less rapid intracellular digestion and breakdown of PHAg's were accompanied by a gradual disappearance of their outer mucopolysaccharide layer. In vitro phagocytosis (60 min in MEM) proceeded in a similar way but more slowly. Coating of PHAg's with immunoglobulin was documented in vitro by ultrastructural enzyme immunocytochemistry. Thus the exudate M phi's are capable of rapid and efficient ingestion of PHAg's which is probably supported in vivo by the interaction of PHAg surface with some exudate components. On the other hand, the intracellular digestion of PHAg's, especially of their mucopolysaccharide shell, is far more protracted.     

In situ fixation of cultured mouse peritoneal exudate cells: Comparison of fixation methods

Summary Mouse peritoneal exudate cells grown in vitro on plastic petri dishes were fixed in situ with both glutaraldehyde and osmium tetroxide by a variety of contemporary methods. The goal of the investigation was to determine which method resulted in the best ultrastructural preservation. The parameters being tested included: (a) the method of fixation, i.e. either sequential or simultaneous; (b) the buffer vehicle for fixation, i.e. cocodylate, Mellonig's phosphate, Sorenson's phosphate, ors-collidine; and (c) the temperature of fixation. Results presented indicate that simultaneous fixation is far superior to sequential methods. Samples fixed sequentially at 4° C consistently had better morphological preservation than samples fixed under similar conditions at 23° C. With the exception ofs-collidine, which was totally unacceptable for in vitro in situ fixation on plastic, comparable results were noted with different buffer vehicles. Previous reports by Cohn and coworkers (1–3) have established that adherent peritoneal exudate cells (PEC) are monocytoid, i.e. macrophages. Thus, in this report, the term adherent peritoneal exudate cells will be used synonymously with macrophages. Supported by a grant from the U.S. Veterans Administration entitled “A Comparative Study of Normal and Activated Macrophages.”     

Trace amounts of enhancing factor/phospholipase A2 in mouse peritoneal exudate cells

Enhancing factor (EF), a mouse phospholipase A₂ (PLA₂), has been purified from the small intestines, based on its ability to increase the binding of epidermal growth factor in a radioreceptor assay. EF/PLA₂ was found to be localized predominantly in the Paneth cells in the small intestines. Whether mouse intestinal EF/PLA₂ is identical/similar to mouse secretory PLA₂ was to be determined. Phospholipases are known to play a crucial role in the process of inflammation. This paper reports the presence of trace amounts of EF/PLA₂ in the peritoneal exudate cells. Western blot analysis of the acid extracts showed the presence of a 14 kDa immunologically cross-reactive protein. RT-PCR analysis using EF specific primers amplified a ∼700 bp product which was further confirmed to be EF-specific by nested PCR analysis and sequencing. Presence of EF in the peritoneal exudate cells could be a unique mode of transport of growth factor modulator to the site of injury to aid in regeneration/cell proliferation of damaged tissue.     

Cytostatic action of the peritoneal cells of Syrian hamsters on transformed cells

The cytostatic effect (CSE) of intact Syrian hamster peritoneal cells (PC) was determined by their capability to inhibit 3H-thymidine incorporation in target cells of HETR, which were placed in 1 X 10(4) or 4 X 10(4) cells per well together with 4 tenfold differing concentrations of PC (10(2)-10(5]. The optimum of CSE was seen with the use of maximal doses of PC and HETR in reaction. Maximal level of CSE with all effector-target cell rations was observed between 23-28 hours of contact. These data permit to suggest the role of HETR cells in activation of PC, as well as the transfer of cytostatic state in dense cell shift mediated by cell-cell contacts. The role of humoral cytostatic factor is also not excluded.     

Antibacterial activity of stimulated guinea pig peritoneal exudate cell culture supernates

Guinea pigs infected with Mycobacterium bovis BCG at least 5 weeks previously yield peritoneal exudate cells which, when stimulated in culture for 2–3 days with specific antigen (PPD), elaborate into the culture medium a factor which is antibacterial for listeria and corynebacteria, but not against other organisms tested. Concentrations of colchicine and vinblastine above 10^?7M completely inhibited its production. The yield of the factor was also found to be dependent on the choice of culture medium, the source of serum, and whether or not the scrum was heated at 56 °C for 30 min. It was weakly antagonized by the anions, RNA, and cyclic and noncyclic nucleotides, but not by lysozyme. It did not lyse M. lysodcikticus and had at least 100 times more activity than egg white lysozyme against listeria. Nonadherent cells from BCG-infected guinea pigs, plus PPD, stimulated adherent monolayer cells from normal guinea pigs to produce this material, but they did not stimulate adherent, cells from rabbit peritoneal exudates to its production.     

Enhancing effect of mouse peritoneal exudate cells and their products on antibody productivity of hybridoma cells: Application of in vivo factors to in vitro culture

Mouse peritoneal exudate cells induced by casein enhanced in vitro antibody production rate per cell of a hybridoma in co-culture. Culture supernatant of the exudate cells also enhanced three-fold the antibody productivity when added to cultures of a hybridoma at 10% (v/v). Hence the enhancement of antibody productivity by the exudate cells seemed to be caused by soluble enhancing factors secreted by the exudate cells. The exudate cells maximally secreted the enhancing factors when harvested from mice on day 4 of the induction period following the injection of casein. A semi-continuous culture of the hybridoma demonstrated the applicability of the culture supernatant to enhance antibody production by producing a two-fold increase over the control for seven days when supplemented with the supernatant at 5%. Significant amounts of interleukin-6 were detected in culture supernatant of the exudate cells. Interleukin-6 obtained from other sources enhanced the antibody productivity two-fold when added to the hybridoma culture at the concentration of 5 unit/ml. Interleukin-6, therefore, is expected to be one of the principal antibody enhancing factors secreted by the exudate cells. Other interleukins examined, that is, interleukin-1 to-5 did not enhance the antibody productivity.     

Induction of different activated phenotypes of mouse peritoneal macrophages grown in different tissue culture media

The role of activated macrophages in the host defense against pathogens or tumor cells has been investigated extensively. Many researchers have been using various culture media in in vitro experiments using macrophages. We previously reported that J774.1/JA-4 macrophage-like cells showed great differences in their activated macrophage phenotypes, such as production of reactive oxygen, nitric oxide (NO) or cytokines depending on the culture medium used, either F-12 (Ham’s F-12 nutrient mixture) or Dulbecco modified Eagle’s medium (DMEM). To examine whether a difference in the culture medium would influence the functions of primary macrophages, we used BALB/c mouse peritoneal macrophages in this study. Among the activated macrophage phenotypes, the expression of inducible NO synthase in LPS- and/or IFN-γ-treated peritoneal macrophages showed the most remarkable differences between F-12 and DMEM; i.e., NO production by LPS- and/or IFN-γ-treated cells was far lower in DMEM than in F-12. Similar results were obtained with C57BL mouse peritoneal macrophages. Besides, dilution of F-12 medium with saline resulted in a slight decrease in NO production, whereas that of DMEM with saline resulted in a significant increase, suggesting the possibility that DMEM contained some inhibitory factor(s) for NO production. However, such a difference in NO production was not observed when macrophage-like cell lines were examined. These results suggest that phenotypes of primary macrophages could be changed significantly with respect to host inflammatory responses by the surrounding environment including nutritional factors and that these altered macrophage phenotypes might influence the biological host defense.     

Inhibition by dietary tea polyphenols of chemical mediator release from rat peritoneal exudate cells

Male Wistar rats were given purified diets containing safflower (SAF), perilla (PER), or palm (PAL) oils with or without 1% tea polyphenols (TP) for 3 weeks, and chemical mediator releasing activity from rat peritoneal exudate cells (PEC) was measured. Histamine releasing activity was not influenced by TP, while histamine release and intracellular histamine content were significantly increased in the PAL-fed group. On the contrary, leukotriene B4 (LTB4) release was significantly lower in rats fed PER than in those fed SAF and PAL, and TP significantly decreased the release in all fat groups. TP also significantly inhibited the release of LTB5, which was generated only in rats fed PER. TP significantly decreased the proportion of arachidonic acid (AA) in PEC in the SAF-fed group and that of eicosapentaenoic acid (EPA), the precursor of LTB5 in the PER-fed group, but did not influence that of AA in the PAL- and PER-fed group. These results suggest that ingestion of TP improves type I allergic symptom through the inhibition of LT release though the inhibition by TP could not be totally explained by the reduction of substrate fatty acid.