Influence of 0.5 ppm nitrogen dioxide exposure of mice on macrophage congregation in the lungs

Summary The lungs of 12 mice, half of which were exposed to continuous 0.5 ppm nitrogen dioxide for 3 weeks, were explanted in culture, and the instances of macrophage congregation were quantitated according to numbers of target cells involved, categories of congregation from three to 11 or more, numbers of macrophages participating in each category for the total cultures, and the influence of delaying explantation for 24 and 96 hr. A total of 9042 macrophages and 2140 epithelial and spindle target cells were counted in the outgrowths from 306 explants. The incidence of macrophage congregation (or numbers of target cells) was greater for the cultures from the NO₂-exposed animals, both with respect to total incidences between groups (p→0), and the 0-hr (p<0.001) and 24-hr (p<0.01) culture subgroups. In addition, the values for T₃ to T₆ macrophage congregation were individually and consistently greater for the exposed animal group. Postmortem interval stress at 96 hr appeared to result in large colonies, but they were reduced greatly in number. Also the incidence of macrophage congregation fell by 28% as compared to 0-hr and 24-hr subgroups. Supported by Grants NHLI No. HL 17412 and EPA No. R. 800881.     

Opposing effects of dexamethasone on the clonal growth of granulocyte and macrophage progenitor cells and on the phagocytic capability of mononuclear phagocytes at different stages of differentiation

Dexamethasone, a synthetic glucocorticosteroid, was shown to modulate the colony-stimulating factor-dependent clonal growth of myeloid progenitor cells in semisolid agar cultures, enhancing the formation of granulocyte colonies (50–100%) and suppressing the formation of macrophage colonies (75–97%). Modulation of the pattern of myeloid colony formation by dexamethasone (12–125 nM) was brought about when the steroid was administered to 6-day cultures at the time of culture initiation and up to 72 hr later. Dexamethasone inhibited myeloid cell proliferation when administered to 5-day liquid cultures at culture initiation and up to 96 hr later. Dexamethasone (12–250 nM) also enhanced the phagocytic activity of bone marrow-derived mononuclear phagocytes toward heat-killed (HK) yeast cells (up to 100%) and IgG-coated sheep red blood cells (up to 60%). Enhancement of the phagocytic capability depended critically on the stage in culture at which dexamethasone was administered. Exposure to dexamethasone for 28 hr up to 96 hr of 96-hr cultures of bone marrow cells did not lead to a modulation of phagocytic activity of the developing mononuclear phagocytes. The presence of dexamethasone during the critical period of 96 hr to 120 hr after culture initiation led to an enhanced phagocytic capability, which was statistically significant already 12 hr after the administration of the glucocorticoid. Dexamethasone induced an enhanced phagocytic activity when administered at any time after culture initiation provided that it was in culture during this critical period. When added at 120 hr of culture, dexamethasone no longer enhanced the phagocytic capability of mononuclear phagocytes and when added later than 156 hr of culture suppressed it. Dexamethasone also suppressed (up to 68%) the phagocytic capability of resident and elicited peritoneal macrophages. The results suggest that glucocorticoids shift the balance of granulocyte vs. macrophage formation at early stages of precursor cell differentiation. Reduction in mononuclear phagocyte growth and enhancement of its phagocytic capability might reflect accelerated differentiation/maturation steps. The inhibitory effect of dexamethasone on macrophage formation and on the phagocytic capability of mature mononuclear phagocytes and peritoneal macrophages might be a relevant aspect of the in vivo immune suppression encountered after glucocorticoid administration.     

Macrophage activation for tumor cytotoxicity: Control of cytotoxic activity by the time interval effector and target cells are exposed to lymphokines

Macrophages continuously exposed to lymphokines (LK) and target cells throughout a 48-hr cytotoxicity assay exhibit 3-fold more tumoricidal activity than do cells optimally treated with LK before addition of tumor cells. Increased cytotoxic activity induced by continuous LK treatment was not due to direct toxic effects of LK on tumor target cells or to alterations in target cell susceptibility to cytopathic effects of LK-activated macrophages. Moreover, sensitivities of responsive macrophages to LK activation signals and time courses for onset and loss of tumoricidal activity during continuous exposure or LK pulse were identical. Analysis of macrophage or LK dose responses and time courses for development of cytotoxicity each suggest that differences in tumoricidal activity between macrophages continuously exposed or pulsed with LK were quantitative: the number of cytotoxic events was increased 2.7 ± 0.2-fold (mean ± SEM for 11 experiments) during continuous LK treatment. Optimal levels of macrophage tumoricidal activity then occur only if effector cells, target cells and activation stimuli are simultaneously present for a defined time interval: tumor cells need not be present during the initial 2 to 3 hr of culture; LK can be removed after 8 hr with little or no loss of cytotoxic activity. However, removal of LK or target cells during the critical 4- to 8-hr interval decreased levels of cytotoxicity 3-fold. Thus, nonspecific effector function by LK-activated macrophages in controlled by both the physicochemical nature of the LK mediator and the time interval effector and target cells are exposed to LK.     

Macrophage activation for tumor cytotoxicity: induction of tumoricidal macrophages by supernatants of PPD-stimulated Bacillus Calmette-Guérin-immune spleen cell cultures.

Resident peritoneal macrophages from normal mice were activated for tumor cytotoxicity in vitro by co-cultivation with BCG1-immune spleen cells and PPD and by incubation with supernatants of PPD-stimulated BCG-immune spleen cell cultures (lymphokine supernatants). Lymphokine activation of macrophages occurred in unfractionated PC suspensions as well as in macrophage monolayers depleted of nonadherent PC. Tumor cytotoxicity by lymphokine-activated macrophages was evident by 3 to 4 hr of culture in active supernatants, reached maximal levels by 8 to 12 hr. and was absent by 20 hr. Continued incubation in lymphokines or even re-exposure after washing did not maintain macrophage cytotoxicity. The capacity of normal resident macrophages to be activated by lymphokines in vitro progressively decreased and was absent by 20 hr in culture. This decrease did not necessarily reflect cell death; macrophage viability as estimated by exclusion of trypan blue or by phagocytic responses did not change over the 20-hr culture period. The short lived nature of both macrophage tumoricidal capacity and capacity of precursor cells to be activated by lymphokines may function as negative feedback mechanisms in immune reactions.     

Macrophages in resistance to rickettsial infection: macrophage activation in vitro for killing of Rickettsia tsutsugamushi.

Rickettsia tsutsugamushi, strain Gilliam, replicates in cultures of resident peritoneal macrophages from BALB/c mice. Macrophage cultures treated with culture supernatants of spleen cells from rickettsial-infected mice stimulated with heat-killed rickettsiae markedly suppressed macrophage infection by rickettsiae. Rickettsiacidal activity of activated macrophages was dependent upon both lymphokine concentration and time of incubation in lymphokines. Treatment of macrophage cultures with lymphokines before exposure to viable rickettsiae resulted in an immediate decrease in percent macrophages infected and numbers of viable intracellular rickettsiae. In these cultures, enhanced intracellular killing was also apparent with further incubation (24 hr). The immediate effect of lymphokine-pretreated macrophages was dissociated from intracellular killing by infecting macrophage cultures first and adding lymphokines after infection. In these cultures, both percent macrophages infected and titers of viable intracellular rickettsiae were dramatically reduced as well.     

Cytostatic activity of in vitro generated macrophages: evidence for a prostaglandin-independent reversible cytostatic mechanism

Culture of spleen cells for 5 days has previously been shown to result in the generation of strongly adherent cells from nonadherent precursors. In the current report it is shown that the majority (85-95%) of adherent cells are Mac-1+, FcR+, Thy 1.2- macrophages. Expression of effector activity by these macrophages requires exposure to activating signals. Coculture of the macrophages with Con A-stimulated spleen cells results in the expression of cytostatic activity against lymphocytic and monocytic tumor cell lines. Significant cytostatic activity is apparent within 6 hr after addition of the activating cells. Culture supernates of Con A-stimulated spleen cells (CAS-CM) are not effective in inducing cytostatic activity in the adherent macrophage population either alone or in the presence of additional Con A. However, stimulation of the culture generated macrophages with LPS in the presence of CAS-CM does induce cytostatic activity. The effector cell must be metabolically active in order to effect cytostasis insofar as heat fixation of the culture generated macrophage population eliminates effector activity. Proliferation of the tumor cells is significantly reduced after a 4-hr incubation period with the activated macrophages and is reduced two- to threefold after an 8- to 12-hr incubation period. The cytostatic effect is rapidly reversible. Proliferative activity of the tumor cells returned to control level within 12-24 hr after removal from activated macrophages. Cell cycle analysis indicated that the target cells were not arrested in a single stage of cell cycle, although an increase in frequency of cells in G1-phase was observed. Fluorescence analysis of bromodeoxyuridine (BrdU) incorporation rate demonstrated that the rate of DNA synthesis was reduced in all of the cells in the target population and that the mean rate of BrdU incorporation of the inhibited cells was three- to fivefold lower than control cells. RNA and protein synthesis were not affected to the same degree as DNA synthesis. The cytostatic effect was not mediated by prostaglandins or thymidine insofar as addition of indomethacin and 2-deoxycytidine did not prevent the cytostatic activity of the macrophages. The supernates of activated macrophages contained little inhibitory activity especially when indomethacin was included in the culture medium (19% inhibition of tumor cell proliferation by 1:1 dilution of supernate). The activity that was present could be eliminated by dialysis against fresh culture medium using Spectropor membranes with a 1000-Da molecular cutoff.(ABSTRACT TRUNCATED AT 400 WORDS)     

Mechanism of nonspecific macrophage-mediated cytotoxicity: evidence for lack of dependence upon oxygen.

Peritoneal macrophages elicited in C3H/HJ mice by the i.p. injection of Corynebacterium parvum were cytotoxic to allogeneic virus-transformed fibroblasts in vitro. Cytotoxicity was demonstrated in a morphologic (plaque) assay, and quantitated by measuring macrophage-mediated inhibition of incorporation of 3H-thymidine by the target cells. The cytotoxic effect was well established by 6 hr of macrophage-fibroblast interaction, and was retained in cultures from which the supernatant was removed before the addition of 3H-thymidine. Cytotoxic activity of macrophages diminished rapidly after 22 hr of cultivation in vitro. Maximal cytotoxic effect could be prolonged by addition of C. parvum, 50 microgram/ml to macrophage monolayers preincubated in vitro for 22 hr. It could neither be retained nor regenerated when C. parvum was added to monolayers greater than 22-hr old. C. parvum-activated macrophages, grown under anaerobic conditions for 8 hr, retained the ability to phagocytize heat-killed Candida albicans and to exclude trypan blue dye. There was a small but significant reduction in the ability of macrophages to inhibit 3H-thymidine incorporation by target fibroblasts under anaerobic conditions. The cytotoxic effect of activated macrophages in air was not altered by the presence of catalase and was enhanced by enzymatically active superoxide dismutase. We conclude that the processes involved in macrophage-mediated cytotoxicity against allogeneic fibroblasts in this system are largely independent of oxygen.     

Activation and mechanism of action of suppressor macrophages

Intravenous administration of Corynebacterium parvum to alloimmunized mice activates splenic suppressor macrophages that effectively curtail primary and secondary generation of cytotoxic T lymphocytes (CTLs) in vitro. CTL generation was significantly inhibited in suppressed primary cultures by Day 3, the earliest time point that activity is first detected in control cultures. Suppressor macrophages had to be present during the first 24–48 hr of culture to effectively curtail the generation of CTLs. However, if suppressor macrophages were reactivated by 48-hr in vitro culture and then added to primary sensitizations that had been initiated 48 hr previously, they were capable of significant suppression. Suppressor cells produced a soluble factor that mediated the inhibition of CTL generation. The production or action of this factor could not be counteracted by indomethacin.     

Effect of capsular polysaccharide of Klebsiella pneumoniae on the differentiation and functional capacity of macrophages cultured in vitro.

The effect of the capsular polysaccharide of Klebsiella pneumoniae (CPS-K) on the differentiation and functional capacity of macrophages cultured in vitro from various lymphoid tissues was investigated. In cultures of peritoneal cells, the number of macrophages did not change throughout incubation periods of from 1 hr to 3 days, and the addition of CPS-K had no affect. It appears therefore that CPS-K does not exhibit cytotoxic effects on macrophages. In cultures of spleen cells, only a small number of macrophages appeared within 1 hr, but the number of macrophages increased during further incubation. The addition of CPS-K to cultures of spleen cells at the start of incubation suppressed markedly the increase in the numbers of macrophage. This finding indicates that CPS-K blocks the process of the generation of macrophages, probably from their precursor cells in cultures of spleen cells. Only a small number of macrophages appeared in cultures of thymocytes or lymph node cells either with or without CPS-K. The phagocytic capacity of either peritoneal macrophages or macrophages generated in cultures of spleen cells was activated during incubation in vitro. Macrophages cultured in the presence of CPS-K for 24 hr or longer appeared to have an enhanced phagocytic activity, although the enhancement of their phagocytic activity by the addition of CPS-K was less marked in cultures of spleen cells than in those of peritoneal macrophages. Morphologically, macrophages in both cultures of peritoneal cells and spleen cells incubated in the presence of CPS-K for 4 days possessed much longer cytoplasmic processes than those incubated in the absence of CPS-K. From the present study, it appears that CPS-K exhibits dual effects on macrophage precursor cells and macrophages, a blocking effect on the differentiation from the former to the latter and an enhancing effect on the functional capacity of the latter.     

Suppressive effect of delta 9-tetrahydrocannabinol in vitro on phagocytosis by murine macrophages

Incubation of normal mouse peritoneal cells consisting of over 90% phagocytizing macrophages with delta 9-tetrahydrocannabinol (THC) resulted in a inhibition of phagocytic function. The THC in a dose-related manner suppressed the percentage of macrophages per culture which ingested yeast and the average number of yeast particles ingested by the phagocytizing macrophages. The vehicle used to suspend the THC in vitro, i.e., DMSO, had no detectable effect on macrophage function. Suppression of phagocytosis with no effects on viability or cell number occurred with doses of 10 micrograms or less THC per milliliter culture medium. Measurable suppression also occurred after 24- to 48-hr treatment of the macrophages with the THC. This compound had little if any detectable effect on phagocytosis when added directly to the cultures shortly before testing for phagocytosis. Further studies concerning the effects of THC on macrophage function appear warranted.     

Macrophage activation to kill Leishmania tropica: kinetics of macrophage response to lymphokines that induce antimicrobial activities against amastigotes

Lymphokine (LK) treatment of resident peritoneal macrophages from C3H/HeN mice induced two antimicrobial activities against Leishmania tropica: increased resistance of activated macrophages to infection with amastigotes and intracellular destruction of those parasites that entered activated cells. The onset and duration of these two antimicrobial activities were quite different. Resistance to infection was observed as early as 4 hr after the addition of LK, became maximal at 8 hr, and persisted in a subpopulation of treated cells for as long as 72 hr. In contrast, intracellular killing occurred with as little as 4 hr of LK treatment after infection, and maximal killing was observed in cultures exposed to LK 24 hr. Intracellular killing capacity of lymphokine-treated cells was progressively lost in macrophages treated longer than 12 hr before exposure to parasites. This decay in ability to destroy intracellular L. tropica was also seen in macrophages cultured longer than 12 hr before LK treatment, and may reflect loss of macrophage responsiveness to LK with increasing time in vitro. Thus, treatment of macrophages with lymphokines induced both a stable change in cell-parasite interactions, resistance to infection, and a short-lived capacity to destroy intracellular amastigotes.     

Macrophage-lymphocyte clusters in the immune response to soluble protein antigen in vitro. IV. Synergy of lymphocytes in the formation of clusters.

T-lymphocyte-enriched lymph node lymphocytes from guinea pigs immunized with Mycobacterium tuberculosis produce clusters with macrophages when cultivated on monolayers of syngeneic purified protein derivative of tuberculin (PPD)-pulsed peritoneal macrophages. The clusters consist of a macrophage with a central lymphocyte attached to it, and several peripheral lymphocytes attached to the central one. By mechanical manipulation immune lymphocytes incubated on monolayers of PPD-pulsed macrophages were separated into those which adhered firmly to the macrophages after 4 hr of culture and those which did not adhere. While neither of the two populations was able to produce significant numbers of clusters alone, they did so in combination. The number of macrophage-lymphocyte clusters which are produced in a culture depends not only on the absolute number of immune lymphocytes in the culture, but also on the concentration of lymphocytes per area of the macrophage monolayer, with high concentrations resulting in high numbers of clusters. Autoradiographic studies showed that the DNA-synthesizing lymphocytes physically associated with macrophages were located mainly inside the clusters in cultures with high concentrations of lymphocytes but mainly outside the clusters in cultures with low concentrations of lymphocytes.     

Circadian phase relationships of thymidine-3H uptake, labeled nuclei, grain counts, and cell division rate in rat corneal epithelium

Significant differences in the uptake of thymidine-³H, percentage of labeled cells, numbers of grains per labeled nucleus, and mitotic rate were noted in rat corneal epithelium along a 24-hr time scale. These were demonstrated by injecting subgroups of five animals every hour during a 24-hr period with thymidine-³H, sacrificing them 2 hr later, and analyzing the corneal epithelium by scintillation counter and radioautographic techniques. The increase in uptake during specific periods of the 24-hr time scale is attributed to an acceleration in the rate of DNA synthesis by individual cells and to an increase in the percentage of cells in the population actively synthesizing DNA.     

Influence of plating density on individual cell growth, cell division and differentiation of neonatal rat heart primary cultures

The influence of plating cell density of an originally enriched myocardial cell population has been studied in neonatal rat heart cells in culture. Low density (LDM) is defined as a density (24 h after plating) of 209 +/- 44 cells/mm2 (mean +/- SEM) and is compared with high density (HDM), 419 +/- 67 cells/mm2. Cell growth is evaluated by the total cell number, the percentage of myocardial cells (M) in culture (PAS method) and the protein content per cell. Some differentiation parameters such as beating rates, glycogen concentration, enzymatic activities (cytochrome C oxidase and glycogen phosphorylase) are studied with time in culture (48, 96 and 192 hr). High density was designed to yield a complete confluency of the cells within 24 hr after plating and to minimize cell division of the non-muscle cells (F). At high density, cell division of F cells is effectively limited, thus leading to a more stable model regarding the cell density per plate and the percentage of M cells: 85.7 +/- 4% and 33.4 +/- 6% in LDM cultures compared with 86.5 +/- 4.7% and 51.7 +/- 9.8% in HDM cultures at 24 and 192 hr (mean +/- SEM). Heart cells increase similarly in size with age in culture in both groups. In HDM cultures the spontaneous contractions begin sooner (24 hr) than in LDM cultures and are more rapidly synchronized. The beating rate is higher in HDM cultures between 48 and 96 hr; however, after this time it falls in HDM and does not fall in LDM. Thus the overgrowth of muscle cells by non-muscle cells is not responsible for loss of beating with time in culture but more likely high density could be a limiting factor for isotonic contraction. There is more glycogen per myocyte in LDM than in HDM cultures. The cell density influences the enzymatic activities of cytochrome C oxidase and glycogen phosphorylase. The cytochrome oxidase activity is higher in HDM cultures than in LDM cultures at 96 hr whereas glycogen phosphorylase activity is higher in LDM cultures at time 96 and 192 hr. In LDM cultures, the ratio cytochrome C oxidase/glycogen phosphorylase decreases with time in culture from 1.685 +/- 0.680 at 48 hr to 0.780 +/- 0.290 at 192 hr but not in HDM cultures (2.13 +/- 0.36 and 1.64 +/- 0.34 respectively). Thus plating density influences properties of heart cell cultures with regard to the overgrowth of the F-cell population and the differentiated state of M cells.     

Induction of tumor cell resistance to macrophage-mediated lysis by preexposure to non-activated macrophages

Thioglycollate-elicited peritoneal exudate (non-activated) macrophages do not lyse tumor cells and in contrast to activated macrophages bind less target cells. However, a non-lethal encounter of tumor cells with non-activated macrophages resulted in a pronounced effect on the subsequent tumor cell binding to and lysis by activated macrophages. Our results have shown that binding of tumor cells by non-activated macrophages was Ca2+ and temperature dependent; had a requirement for a Pronase-sensitive structure on macrophage surface membranes; was saturable; and was 2-3X less than that observed for activated macrophages. Experiments were conducted in which syngeneic tumor cells were incubated with a monolayer of non-activated macrophages and then assayed for selective binding and sensitivity to lysis. The important observations were that as a result of a 3-hr incubation with non-activated macrophages at an EC: TC ratio of 5:1 there was an increase in the number of tumor cells that bound to both activated and non-activated macrophages; a loss of selective binding in which the ratio of tumor cells bound to activated/non-activated macrophages (normally greater than 2) was lowered to 1.0; and a concomitant decrease in the susceptibility of tumor cells to macrophage-mediated cytolysis. The induction of tumor cell resistance to macrophage kill required an exposure to an excess number of non-activated macrophages, was reversible upon culturing with or without macrophages for 24 hr and required cell-cell contact. Our results reinforce the importance of selective binding between tumor cells and activated macrophages as an initial phase in tumor cell killing and also illustrates an active role for non-activated macrophages in vivo in allowing tumor cells to escape the immune surveillance by activated macrophages.     

Sequential study on the influence of adriamycin on cell proliferation and ultrastructure of cultured mammary tumor cells

The time-dependent cytocidal and growth inhibitory effects of Adriamycin (ADM) on monolayer cultures of 7,12-dimethylbenz[a]anthracene (DMBA)-induced mammary tumor cells were analyzed. The inhibitory effect on cell proliferation was assessed by colony formation in soft agar. Growth inhibition and [3H]thymidine labeling indices clearly demonstrate a dose-dependent antimitotic and cytotoxic effect of the drug. At low concentrations (10(-9)-10(-8) M), 90-100% of cells survived 24-hr exposure. At a higher concentration (10(-5) M), 75-80% of cells survived after 8-hr exposure; by 72 hr only 20-30% of the cells remained. Autoradiographic examination of the pulse-labeled cultures demonstrated no change in the proportion of cells in S-phase during the first 4 hr of treatment. Subsequently DNA synthesis was completely abolished and remained inhibited for the duration of the experiment (72 hr). Clonogenic assay revealed a complete arrest of growth in cells exposed to 10(-5) M ADM and greater than 60% inhibition of cell proliferation at 10(-7) M. Ultrastructural changes were not observed in cells during the first 4 hr of treatment; however, after 8 hr most surviving cells exhibited alterations in nuclear chromatin. The surviving cells showed mitochondrial degeneration, myelin body formation, and vacuolization of the endoplasmic reticulum. This study shows the potential usefulness of the primary culture system in drug evaluation. In addition, serial observation of the effects of ADM revealed a cell subpopulation of the primary culture with differential sensitivity to the drug.     

Stimulation by granulocyte-macrophage colony-stimulating factor of Leishmania tropica killing by macrophages.

The intracellular protozoan parasite Leishmania tropica was found to survive unharmed and to multiply for several days in normal mouse peritoneal macrophages. In contrast, when infected monolayers were treated with GM-CSF, there was a continuous decrease in the percentage of infected cells, reaching less than 10% on day 4 in culture, compared to about 30% in normal controls. Microscopic observations showed an increased number of dead parasites in GM-CSF treated infected cells. Within 5 hr of incubation with GM-CSF, almost 40% of intracellular parasites showed morphologic damage, compared to less than 10% in untreated cells. Pretreatment of macrophage monolayers with pure GM-CSF before infection led to an increased level of phagocytosis of L. tropica parasites as reflected by the percentage of infected cells and the increased number of parasites in each infected cell. GM-CSF treated cultures showed 73% infected cells containing a mean of five parasites per cell, as compared to controls in which only about 50% of macrophages were infected with only two parasites per cell. The number of dead parasites per cell was 5-fold higher in the GM-CSF treated cultures at 2 hr. After 24 hr the percentage of infected GM-CSF treated cells was less than one-third that in the control cultures.     

Stimulation by conditioned medium of L-929 fibroblasts, E. coli lipopolysaccharide,and muramyl dipeptide of candidacidal activity of mouse macrophages

A simple, quantitative assay method for microbicidal activity of phagocytic cells was devised using normal mouse peritoneal macrophages as effector cells and Candida parapsilosis as target cells. The macrophages were seeded in 96-multiwell tissue culture plates and infected with serially diluted Candida cells. Outgrowth of Candida cells in each well was estimated after a 48-hr incubation period. The maximum number of microbes killed on macrophage monolayers was then determined. The conditioned medium of L-929 cells (L-CM) influenced the fungicidal activity of the macrophages a great deal. An addition of L-CM, to 20% of the culture medium, stimulated the killing activity more than 128-fold, compared with no addition of L-CM. In the medium containing the L-CM macrophages spread very well on the plastic with several dendritic processes, whereas cells spread poorly and gradually cytolysed in the medium lacking L-CM. It was found that muramyl dipeptide at 100 μg/ml and E. coli lipopolysaccharide at 1–10 μg/ml stimulated the activity 4 to 16 times. An application of this method to destroying other kinds of microbes, measuring the activity of other phagocytes, and screening immunomodulators was discussed.     

Regulation by PGE2 of the production of oxygen intermediates by LPS-activated macrophages

The regulation by prostaglandin E2 (PGE2) of production of oxygen radicals by bacterial lipopolysaccharide-(LPS) activated macrophages was studied in vitro. A 48-hr incubation of murine thioglycollate-elicited macrophages with LPS (0.1 micrograms/ml) resulted in an enhanced ability of these cells to produce oxygen radicals when challenged with phorbol myristate acetate (PMA). Macrophages incubated for 48 hr without LPS did not produce measurable amounts of oxygen radicals when exposed to this triggering stimulus. Thus, PMA-triggered production of oxygen radicals was the result of macrophage activation by LPS. The PMA-triggered production of oxygen radicals by the LPS-activated macrophages was inhibited when PGE2 (10(-5) to 10(-9) M) was present during the incubation with LPS. Inhibition by PGE2 occurred during the early stages of macrophage activation, since the addition of PGE2 24 hr after LPS no longer inhibited the production of oxygen radicals by the macrophages. This inhibitory effect of PGE2 on the LPS-induced activation of macrophages could be reproduced by cyclic-adenosine-monophosphate (cAMP) agonists, such as isoproterenol and cholera toxin as well as by the cAMP analog dibutyryl-cAMP, suggesting a cAMP-mediated mechanism for the inhibitory effect of PGE2 on macrophage activation by LPS. Previous reports have implicated prostaglandins as mediators of destructive processes associated with chronic inflammation. Our findings suggest that PGE2 may, on the other hand, reduce tissue damage in a chronic inflammatory site by inhibiting the production of oxygen radicals by macrophages activated in the sera.     

Transforming growth factor beta (TGF-beta) inhibits hepatocyte DNA synthesis independently of EGF binding and EGF receptor autophosphorylation

Subpicomolar concentrations of human platelet-derived transforming growth factor beta (TGF-beta) inhibited growth factor-stimulated DNA synthesis in primary cultures of adult rat hepatocytes. This inhibition was not the result of changes in the size of intracellular pools of 3H-thymidine and was not dependent on the state of confluence of the cells. A 24-hr exposure to TGF-beta either before or after insulin/EGF stimulation was as inhibitory on DNA synthesis between 48 and 72 hr of culture as was TGF-beta present throughout 72 hr of culture. From 12 hr in culture to 24 hr, hepatocyte EGF binding sites dropped from about 230,000 to 85,000 per cell with no significant change in Kd, but with a loss in capacity for EGF-induced receptor down-regulation. Maximally inhibitory concentrations of TGF-beta did not compete with EGF for the EGF receptor, and a 4- to 24-hr exposure to TGF-beta did not alter subsequent EGF binding. Coincubation of hepatocytes with TGF-beta and EGF did not influence the 60% reduction in EGF binding sites produced by EGF alone. In addition, TGF-beta did not prevent EGF-induced autophosphorylation of the 170,000 dalton EGF receptor in membranes from whole liver. Our studies suggest that TGF-beta regulates hepatocyte growth independently of changes in EGF receptor number, ligand affinity, or postbinding autophosphorylation.