Enhancing and suppressive effects of macrophages on T-lymphocyte stimulation in vitro.

The immunoregulatory effect of peritoneal and splenic macrophages on Con A-stimulated mouse splenic T lymphocytes was investigated in vitro using [¹²⁵I]UdR incorporation as a measure of lymphocyte proliferation. [¹²⁵I]UdR incorporation was enhanced by the addition of increasing numbers of splenic or low doses of peritoneal adherent cells to macrophagedepleted splenic lymphocytes. The addition of increasing numbers of peritoneal macrophages beyond 5–10%, however, proportionally suppressed T-cell proliferation. Activated splenic macrophages obtained from mice 6 days after infection with Listeria monocytogenes were suppressive, whereas macrophages obtained from immune donors 9–10 days after infection were not, so that a chronological association appeared to exist between macrophage activation and immunosuppression. The addition of 2-mercaptoethanol to the cell cultures increased [¹²⁵I]UdR incorporation without affecting the stimulatory and suppressive effects of splenic and peritoneal macrophages, respectively. Heat-killed and freeze-thawed macrophages lost their capacity to enhance or inhibit lymphocyte transformation. Macrophages treated with mitomycin C to inhibit DNA synthesis retained their regulatory functions. These studies suggest differential regulatory roles for spleen versus peritoneal macrophages on T-lymphocyte responses to Con A stimulation in vitro.     

The polyvalent protease inhibitor, trasylol, inhibits DNA synthesis of mouse lymphocytes by an indirect mechanism.

By the use of incorporation of radiolabeled thymidine, uridine, and leucine into mouse lymphocytes, the inhibitory effect of the protease inhibitor, trasylol, on antigenor mitogen-induced lymphocyte triggering was studied in vitro. DNA synthesis, as well as RNA and protein syntheses, were effectively inhibited by 0.3–2.5 × 10^?7 mol of trasylol when responses were induced by homologous antigen, allogeneic cells, phytohemagglutinin, or endotoxic lipopolysaccharide of Escherichia coli. The inhibitory effect of trasylol was reversible. On the contrary, DNA synthesis by nonadherent spleen cells was hardly inhibited by the inhibitor when the cells were stimulated with a relatively large amount of concanavalin A. Antigen-induced DNA synthesis by non-adherent lymph node cells was enhanced by the culture supernatant of macrophages. This helping effect of macrophage supernatant was effectively inhibited either by soluble or insoluble trasylol. These results suggest that the inhibitory action of trasylol on lymphocyte triggering may operate indirectly to interfere with the helping action of macrophages on lymphocytes.     

The effects of activated macrophages on tumor target cells: Escape from cytostasis

In contrast to normal mouse peritoneal macrophages, activated macrophages almost totally inhibit [³H]TdR uptake by tumor target cells 24 hr after challenge. However, when the period of observation was extended to 48 or 72 hr, renewed [³H]TdR uptake by target cells was often, but not always, observed in the presence of activated macrophages. This apparent escape of target cells from the cytostatic effects of activated macrophages was not due to a subpopulation of resistant target cells, and autoradiographic studies revealed that target cells, inhibited from incorporating [³H]TdR by activated macrophages at 24 hr, were subsequently able to renew DNA synthesis and multiply. These results suggest that in the presence of activated macrophages, the almost total cytostasis of target cells does not necessarily mean that these cells are irreversibly damaged or killed.Escape from or maintenance of cytostasis was not peculiar to any of the target cells (L cells, EMT-6, Bladder 4934) or mouse strains (SW, C57BL, BALB/c) employed nor was it consistent with any of the forms of stimulation used for obtaining activated macrophages (Toxoplasma or Besnoitia infection; C. parvum treatment). However, the results suggest that when escape of target cells from the cytostatic effects of activated macrophages occurred, it may have been due to a qualitative or quantitative inadequacy of the population of macrophages employed.     

Macrophage regulation of DNA synthesis in lymphoid cells: effects of a soluble factor from macrophages

Addition of rat peritoneal macrophages to nonadherent rat spleen cells in culture results in enhancement or suppression of DNA synthesis depending on the ratio of macrophages to lymphocytes. At high ratios of macrophages to lymphocytes (1:5), suppression can be observed as early as four hours. Macrophages suppress incorporation of thymidine (TdR) by nonadherent spleen, thymus and bone marrow cells, in most instances, to less than 5% of that observed in culture to which macrophages were not added. In the presence of macrophages, incorporation of [³H]uridine and [¹⁴C] amino acids by spleen cells was also moderately suppressed. Based on ⁵¹Chromium release and dye exclusion assays, it appears that suppression is not due to cytotoxicity. Furthermore, suppression of [³H]TdR incorporation by nonadherent spleen cells is reversible, in the presence of an antigenic stimulus, following removal of the macrophages from the cultures. The suppressive effects are not elicited by extracts of macrophages, freeze-thawed or heated macrophages, but appear to be due to a low molecular weight, heat stable factor released into the macrophage culture fluid.     

Inhibition of 3H-thymidine incorporation of lymphocytes by a soluble factor from macrophages

Supernatants of peritoneal macrophages cocultivated with spleen cells or thymocytes contain a factor suppressing the ³H-thymidine (³H-TdR) incorporation of PHA-stimulated lymphocytes. The suppressing activity is not due to cytotoxicity and does not affect the rate of cell transformation or cell proliferation. The factor reduces only the ³H-TdR incorporation and not the DNA synthesis of lymphocytes. It does not show target cell specificity. The factor is dialysable, heat stable, and generated by macrophages.     

Effects of removing PHA from cultures of PHA-stimulated lymphocytes

The proliferative capacity of PHA-stimulated lymphocytes following removal of PHA from the cultures was investigated. Lymphocytes were incubated with different PHA concentrations for 3 or 24 h and were then cultured in fresh medium with or without PHA in the original concentration. Cell proliferation was measured by incorporation of ³H-TdR. The effect of removing PHA was found to vary with the PHA concentration used for stimulation. Thus removal of PHA at 3 and 24 h from cells stimulated with half the optimal and at 3 h from cells stimulated with optimal PHA concentrations inhibited thymidine incorporation almost completely. Removal at 24 h from the latter cells resulted in a moderately decreased thymidine incorporation, whereas no decrease was seen after the removal of PHA from cells stimulated with twice the optimal concentration. When the cells were stimulated with very high PHA concentrations (20 × optimal), removal of PHA even resulted in an increased thymidine incorporation, a phenomenon that most probably has to do with the utilization of exogenous thymidine being inhibited by high PHA concentrations.The decreased thymidine incorporation after removal of low PHA concentrations was due to a reduction in the number of cells entering the proliferation cycle as well as to a decreased multiplication of cells already in DNA synthesis. This shows that PHA stimulates the cells even after they have initiated DNA synthesis. Various explanations for the results are discussed.     

Differential production of interferon and lymphotoxin by human tonsil lymphocytes.

Lymphotoxin (LT) production, interferon (IF) production, and DNA synthesis were investigated after mitogen stimulation and in the mixed lymphocyte culture (MLC) reaction using human tonsil lymphocytes. Both LT and IF were assayed in parallel and from the same lymphocyte supernatants. An analysis of the PHA, PWM, one-way and two-way MLC reactions showed that the amounts of LT and IF produced could not be correlated. Polyriboinosinic: polyribocytidylic acid (poly(I: C)) failed to induce either LT production or [³H]TdR incorporation but did induce IF production. Removal of glass-adherent cells (GAC) had no effect on mitogen induced LT production but their removal reduced LT production in MLC reactions. GAC were necessary for IF production and optimal [³H]TdR incorporation in both mitogen stimulated cultures and in MLC reactions. IF and LT activities were shown to be the result of different molecules by using a Sephadex G-75 column. These results indicate that mitogen stimulation differs from MLC reactions in the cell type or control mechanisms involved for LT production, and that in mitogen stimulated cultures all three of these in vitro phenomena are probably the results of either different cell types or of different cell to cell interactions.     

Composition of splenic T lymphocytes in allophenic mice.

Guinea pig peritoneal macrophages were activated in vitro by culturing with MAF (macrophage activating factor)-containing fractions from stimulated lymphocytes. These macrophage preparations demonstrate a 60% increase in the production of prostaglandins of the E series (PGE) when compared with macrophages cultured with fractions from unstimulated lymphocytes. PGE accumulation in macrophage cultures is maximal after 24 hr with MAF; tumor cytotoxicity is also maximal at this time. The final PGE concentration in cultures of activated macrophages averaged 3 × 10^?8M.     

Products of lipopolysaccharide-activated macrophages (tumor necrosis factor-alpha, transforming growth factor-beta) but not lipopolysaccharide modify DNA synthesis by rat trophoblast cells exhibiting the 80-kDa lipopolysaccharide-binding protein

Pregnancy losses from gram negative bacterial infections could be caused by direct effects of LPS on placental cells, or indirectly via LPS activation of macrophages in the uteroplacental unit. To evaluate those alternatives, LPS, LPS-activated peritoneal cells, conditioned medium from LPS-activated peritoneal cells, and some purified and recombinant molecules known to be secreted by activated macrophages were tested for their abilities to modify DNA synthesis by rat trophoblast cells. Three trophoblast cell lines derived from midgestation placentas of outbred and inbred rats were used for the experiments. Although the 80-kDa LPS-binding protein was demonstrated on trophoblast cells, LPS alone had no effect on the ability of trophoblast cells to synthesize DNA. In cocultures, trophoblast cell DNA synthesis was slightly enhanced by low concentrations of both unstimulated and LPS-activated peritoneal cells. At higher concentrations, LPS-activated cells caused significant inhibition of DNA synthesis by trophoblast cells. Conditioned media from LPS-activated peritoneal cells were highly inhibitory to trophoblast cell DNA synthesis. When specific molecules likely to be components of those media were tested, IL-1 was found to have a modest but reproducible stimulatory effect and PGE2 did not change trophoblast cell incorporation of [3H]TdR. In contrast, trophoblast cell DNA synthesis was markedly inhibited in a dose-dependent manner by both TNF-alpha and TGF-beta 1. No differences in the sensitivity of trophoblast cells from outbred and inbred rats were observed. Given the limitations of the experimental model system, the results suggest that in cases of infection by gram-negative bacteria LPS may have an adverse effect on pregnancy by stimulating resident macrophages to generate and release molecules that are inhibitory to trophoblast cell DNA synthesis.     

Interaction of Bacillus Calmette--Guérin-activated macrophages and neoplastic cells in vitro II. The relationship of selective binding to cytolysis

5′-Methylthioadenosine (MTA), a degradation product of S-adenosylmethionine, inhibits DNA and protein synthesis as well as cellular proliferation in human lymphocyte cultures stimulated with mitogens, antigens, or allogeneic cells. MTA (10^?3M) inhibited [³H]Tdy uptake in PHA- or Con A-induced transformation greater than 95%, and inhibited the uptake of both [³H]Tdy and [¹⁴C]Leu to the same degree in lymphocytes stimulated with PPD or allogeneic lymphocytes. MTA inhibition was dose dependent, inhibition being lost when exogenous levels reached approximately 10^?5M. The inhibitory effects of MTA were not produced by cytotoxicity since MTA-inhibited cells washed free of this compound could be stimulated at least as well as uninhibited cells. Understanding the mode of action of MTA and the mechanisms controlling its metabolism may lead to new approaches for regulating cellular proliferation.     

Preparation, characterization, and functions of rabbit lymph node populations. III. Antigen-induced uptake of thymidine and dibutyryl cyclic AMP: inhibition of thymidine uptake by cholera toxin and dibutyryl cyclic AMP.

Keyhole limpet hemocyanin (KLH)-primed lymph node cell (LNC) populations were incubated with various amounts of KLH and the cellular incorporation of tritiated thymidine ([³H]TdR) or tritiated N⁶, O^2′ dibutyryl cyclic AMP ([³H]DbcAMP) was determined. T LNC responded more vigorously than did complement receptor lymphocytes (CRL), i.e., B cells, at all KLH concentrations, during all time intervals examined, and in the presence or absence of normal rabbit serum (NRS). The depletion of adherent cells from KLH-primed LNC resulted in no significant decrease in KLH-induced incorporation of either [³H]TdR or [³H]DbcAMP in any of the LNC populations. Thus it appeared that variation among LNC populations in the incidence of macrophages did not account for the marked variation in their responses. Cultures containing equal numbers of T and CRL were induced to incorporate more [³H]TdR or [³H]DbcAMP than either population cultured separately or the sum of their individual responses. It was concluded that KLH-induced incorporation of these substances into primed, isolated LNC, was primarily manifested in the T-cell population. The synergism seen in cultures containing mixtures of T and CRL suggested that B cells are induced to incorporate [³H]TdR or [³H]DbcAMP in the presence of antigen and T-cell product(s). KLH-induced incorporation of [³H]TdR into KLH-primed LNC was inhibited by cholera enterotoxin (CT) and DbcAMP as previously reported. However, CT or DbcAMP inhibited this incorporation into T LNC to a greater extent than into CRL or unfractionated LNC.     

Activation of lymphoid cells by BCG in vitro

Bacillus Calmette-Guerin (BCG) stimulated splenic and thymic lymphocytes in vitro as measured by uptake of ³H-thymidine. This activation of lymphocytes by BCG required the presence of a critical concentration of macrophages. Thymus cells containing no more than 0.25% macrophages were stimulated by BCG, but reduction of macrophages below this level by adherence to plastic abolished the response. Reconstitution with purified macrophages completely restored the response. A high concentration of adherent cells (“macrophages”) depressed the response of splenic lymphocytes, as judged by the improvement in DNA synthesis after reduction of the proportion of adherent cells in the spleen cell population.Bacillus Calmette-Guerin augmented the production of lymphocyte-activating factor (LAF) from purified splenic adherent cells, but the presence of lymphocytes made that augmentation considerably greater.These data reaffirm the bidirectional nature of the relationship between lymphocytes and macrophages. They further show that BCG can create highly activated populations of each type of cell, in part by enhancing their interaction.     

Suppression of lymphokine production: I. Macrophage-mediated inhibition of MIF production

Macrophages have been found to suppress the in vitro production by stimulated T lymphocytes of a lymphokine, migration inhibitory factor. When macrophages isolated from primary MSV-induced tumors were added to antigen-stimulated MSV-immune spleen cells, a complete suppression of MIF production was observed. This suppression was nonspecific, since MIF production by antigen-stimulated alloimmune spleen cells and by PHA-stimulated normal spleen cells was also inhibited. Suppressor macrophages could also be induced by inoculation with Corynebacterium parvum, whereas light mineral oil-induced peritoneal macrophages had no detectable effect on MIF production. The failure to detect MIF in the supernatants of stimulated cultures containing activated macrophages appeared to be due to inhibition of lymphokine production rather than to absorption or inactivation of MIF or to interference with the assay for detection of MIF. Macrophages were able to suppress MIF production only when added during the first 4–5 hr of culture and they had no effect when added later. These data show that activated macrophages can nonspecifically suppress lymphokine production and that this appears to be due to inhibition of an early step in lymphocyte stimulation.     

CHARACTERIZATION OF LYMPHOCYTE TRANSFORMATION INDUCED BY ZINC IONS

Lymphocyte cultures from all normal human adults are stimulated by zinc ions to increase DNA and RNA synthesis and undergo blast transformation. Optimal stimulation occurs at 0.1 mM Zn⁺⁺. Examination of the effects of other divalent cations reveals that 0.01 mM Hg⁺⁺ also stimulates lymphocyte DNA synthesis. Ca⁺⁺ and Mg⁺⁺ do not affect DNA synthesis in this culture system, while Mn⁺⁺, Co⁺⁺, Cd⁺⁺, Cu⁺⁺, and Ni⁺⁺ at concentrations of 10^-7–10^-3 M are inhibitory. DNA and RNA synthesis and blast transformation begin to increase after cultures are incubated for 2–3 days with Zn⁺⁺ and these processes reach a maximum rate after 6 days. The increase in Zn⁺⁺-stimulated lymphocyte DNA synthesis is prevented by rendering cells incapable of DNA-dependent RNA synthesis with actinomycin D or by blocking protein synthesis with cycloheximide or puromycin. Zn⁺⁺-stimulated DNA synthesis is also partially inhibited by 5'-AMP and chloramphenicol. Zn⁺⁺ must be present for the entire 6-day culture period to produce maximum stimulation of DNA synthesis. In contrast to its ability to independently stimulate DNA synthesis, 0.1 mM Zn⁺⁺ inhibits DNA synthesis in phytohemagglutinin-stimulated lymphocytes and L1210 lymphoblasts.     

Lymphocyte responses to syngeneic antigens. I. Enhancement of the murine autologous mixed lymphocyte response by polyethylene glycol

The normally weak murine T-cell proliferative response against autologous non-T stimulator cells (the autologous mixed lymphocyte culture (MLC) was enhanced markedly by inclusion of the hydrophilic polymer, polyethylene glycol (PEG), into the culture medium. Potentiation of the autologous MLC was indicated on the basis of increased [³H]TdR incorporation by responding cells, as well as by the numbers of viable cells recovered from mixed cell cultures. PEG is not a polyclonal activator of T and/or B lymphocytes, since nylon wool nonadherent lymphoid cells (T cell-enriched fraction), nylon wool adherent cells (B cell-enriched fraction) and T cell-deficient “nude” spleen cells were not stimulated into DNA synthesis when cultured separately with PEG. Inclusion of 4% PEG into the culture medium was found to optimally enhance autologous MLC, although concentrations between 2 and 5% also significantly elevated responsiveness. At a responder/stimulator ratio of 1:2, autologous MLC yielded peak [³H]TdR incorporation after 5 days of culture. At lower ratios (1:1 and 2:1), however, Δ cpm of autologous MLC continued to increase over a culture period of 7 days. Enhanced responsiveness in the presence of PEG was observed in strains of mice representing a variety of H-2 haplotypes, indicating that at least the potential for autoreactivity of this type is a naturally occurring and widespread characteristic of murine species. An absolute requirement for purified T responder cells was necessary in the autologous MLC, since unseparated lymphoid cell responder LN or spleen cells demonstrated marked proliferation when cultured alone in medium containing PEG. The proliferation of T cells to autologous non-T cells within the same unseparated lymphoid cell preparation appears to be responsible for this phenomenon. Ia antigens expressed by the stimulator cells are involved in the induction of T-cell response, since anti-Ia sera added directly to the cultures inhibited the autologous MLC, but did not affect other T-cell responses to alloantigens or mitogens. Despite the marked proliferation observed in the autologous MLC performed in the presence of PEG, there was no generation of cytotoxic effector cells. Thus, PEG does not appear to add, or alter determinants on stimulator cells to an extent that they are recognized as foreign by precursor cytotoxic T cells. Although the mechanism of enhancement of autologous MLC by PEG is not totally defined, it appears, at least functionally, to promote cellular interactions that occur normally between T cells, B cells, and macrophages. In this respect, PEG will be a powerful and useful probe to dissect the cellular interactions that take place in autologous responses.     

Effect of arabinosyl cytosine on the level of DNA polymerase and thymidine kinase activity in PHA-stimulated human tonsillar lymphocytes

Summary The effect of arabinosyl cytosine (ara-C) was studied on the uptake, phosphorylation and incorporation of ³H-thymidine in human tonsillar lymphocyte cultures is described along with its effect on the level of DNA polymerase and thymidine kinase activities induced by phytohaemagglutinin (PHA). Freshly isolated tonsillar lymphocytes are stimulated cells with a remarkably high activity of DNA polymerase a and thymidine kinase. During in vitro culture, these stimulated cells are transformed to the resting state with low DNA polymerase and thymidine kinase activity. However, a new DNA synthesising cycle can be induced by PHA with maximum at 48 h.10^–6 M ara-C inhibited the incorporation of ³H-thymidine by 90–95%. This inhibition may be reversed by rinsing the cells. The inhibition of the transport of ³H-thymidine seems to be only a consequence of the inhibitory effect of ara-C on the DNA polymerisation reaction, because at 10 °C, where DNA synthesis was arrested, ara-C does not influence the uptake and the phosphorylation of ³H-thymidine.Ara-C (10^–6 M) abolished also the PHA induced elevation of DNA polymerase a and thymidine kinase activities without influencing protein synthesis of the cell. This supports a coordinated regulation mechanism between DNA synthesis and the synthesis of enzymes involved in DNA replication.     

Lymphocyte and macrophage adenyl cyclase activity in animals with enhanced cell-mediated resistance to infection and tumors.

As cyclic AMP has been associated with the inhibition of lymphocyte cytotoxicity, studies were performed to investigate adenyl cyclase activity in lymphocytes and macrophages of Toxoplasma-infected mice in which the efferent limb of the cell-mediated immune response had previously been found to be activated. In peritoneal or splenic lymphocytes from $\text{Balb}\text{c}$ mice chronically infected with Toxoplasma in which growth of an isogeneic bladder tumor was found to be inhibited, adenyl cyclase activity was significantly less than in lymphocytes from uninfected control mice. Stimulation by prostaglandin E₁ or NaF in vitro led to higher levels of adenyl cyclase activity in lymphocytes from unifected animals than in cells from Toxoplasma-infected animals. Similar observations were made with peritoneal macrophages from Toxoplasma-infected and uninfected mice. Lower levels of adenyl cyclase activity were also found in lymphocytes from tumor-bearing mice than in lymphocytes from nontumor-bearing controls. These data suggest that production of cyclic AMP by lymphocytes is inhibited with activation of certain cell-mediated immune functions.     

HUMAN MONOCYTES AND MACROPHAGES : Interaction with Antigen and Lymphocytes

PPD-sensitized monocytes and macrophages from tuberculin-positive subjects are both capable of inducing blastogenic transformation of autologous lymphocytes. Incorporation of thymidine-³H and morphological transformation were always greater in lymphocyte cultures containing macrophages than in those containing monocytes. More lymphocytes entered the first detectable S phase in cultures containing macrophages. Lymphocyte DNA synthesis occurred as early as 40 hr of culture and always in cells in contact with mononuclear phagocytes. By 120–144 hr, many transformed lymphocytes were free in suspension; at the same time, the "immunological cluster" had increased greatly in size and contained transformed and untransformed lymphocytes. The greater effectiveness of macrophages at induction of lymphocyte transformation may be related to the efficiency of this cell type at trapping antigen and its effectiveness at making contact with and binding lymphocytes.     

Peritoneal macrophages exposed to purified macrophage colony-stimulating factor (M-CSF) suppress mitogen- and antigen-stimulated lymphocyte proliferation

The effect of M-CSF-exposed macrophages on murine splenic lymphocyte responses was determined. Resident peritoneal macrophages incubated with purified M-CSF for 48 hr inhibited lymphocyte proliferation to Con A, PHA, and listerial antigen as determined by [3H]TdR uptake, and inhibited Con A-stimulated lymphocyte IL 2 production. The inhibition was similar to that observed with macrophages from BCG-infected mice. Maximal suppression occurred at M-CSF concentrations of 500 U/ml or greater and when the incubation time with M-CSF was 48 hr or more. M-CSF effect was specific because rabbit anti-M-CSF IgG blocked the suppression whereas control rabbit IgG did not. Secretory products of macrophages could not be implicated in this interaction. Catalase and indomethacin, alone or together, did not reverse the inhibition. In addition, putative suppressive factors were not detected in supernatants of M-CSF-stimulated macrophages. Lymphocytes that were removed from macrophage monolayers and were recultured in medium plus Con A were able to proliferate. Macrophages stimulated by M-CSF therefore appear to have inhibitory activity for proliferating lymphocytes, and may play a role in immunoregulatory mechanisms.     

3H-uridine incorporation as a T lymphocyte indicator in the rat

Although about 70% of rat thoracic duct small lymphocytes labeled readily in vitro with ³H-uridine, only 3–38% of peritoneal exudate lymphocytes labeled. Since exudate cells are mostly B lymphocytes, ³H-uridine in concentrations used were presumed to label the T lymphocyte. Percentages of small lymphocytes that labeled in cell suspensions from various tissues were consistent with other estimates of T cells in those sources: 74.7% in thoracic duct, 70.2% in blood and 65.6% in spleen. When lymphopenia was induced by polyethylene ³²P strips applied to the spleen, a procedure that depletes mostly small recirculating lymphocytes, both labeled (T) and nonlabeled (B) cells were depleted in similar time sequence. Both cell types recovered at a similar rate after the spleen strips were removed. Induction of peritoneal inflammation by PPD in tubercle-bacilli immune rats caused an enhanced lymphocytic exudation but no increase in percentage of labeled (T) lymphocytes.The defect in ³H-uridine incorporation that characterizes the rat B lymphocyte seemed to be relatively specific for that RNA precurser; ³H-cytidine labeled the majority of lymphocytes in peritoneal exudate.