Apolipoprotein E is a biologically active constituent of the normal immunoregulatory lipoprotein, LDL-In

A normal plasma lipoprotein, termed LDL-In, has been shown to be a potent inhibitor of mitogen-driven human lymphocyte proliferation in vitro and of primary antibody responses in the mouse. To determine whether the immunoregulatory activity of LDL-In resided with the protein rather than the lipid constituents of LDL-In, one of the apoproteins of LDL-In, apoprotein E, was isolated from plasma and was analyzed for its inhibitory activity. Apoprotein E, isolated after delipidization of lipoproteins with either methyl ethyl ketone or ethanol and ethyl ether, was immunosuppressive. Furthermore, the characteristics of inhibition of cellular [3H]thymidine uptake by isolated apoprotein E were identical to those characteristics obtained with suppression by LDL-In. Inhibition by apoprotein E and LDL-In required preincubation of the cells with either apoprotein or lipoprotein for 24 hr before exposure of the cells to mitogen for maximal expression of suppressive activity, and this inhibition could not be reversed by removal of non-cell-associated inhibitor before stimulation. Neither apoprotein E or LDL-In was inhibitory when they were added to the cells after mitogen stimulation. The only difference noted between suppression by apoprotein E and LDL-In was that of dose. Compared with quantitative estimates of the apoprotein E content of LDL-In, significantly more isolated apoprotein E was required than lipoprotein-associated E for comparable levels of suppression. The potency of apoprotein E could be increased by adding it to cells in the presence of dimyristoylphosphatidylcholine/cholesterol vesicles. The data suggesting that phospholipid increased the specific activity of apoprotein E by altering its molecular dispersion was obtained from analyses of the interaction of apo E with cells, as well as the plastic culture vessels. The results suggested that the molecular dispersion and perhaps organization of isolated apoprotein E in an aqueous system is critical to its interaction with lymphocytes and subsequently its biological activity.     

Direct suppression of lymphocyte induction by the immunoregulatory human serum low density lipoprotein, LDL-In

Preparations of LDL-In, an immunosuppressive lipoprotein subfraction, were analyzed for the capacity to directly suppress the response of human lymphocytes to the representative stimulant PHA vis-a-vis indirect mechanisms mediated by soluble factors or cell:cell interactions. Serum lipoprotein subfraction enriched in LDL-In induced a suppressed state in lymphocytes during 18-hr induction cultures. These lymphocytes, whether partially or completely suppressed, when added to fresh responder lymphocytes in the presence of PHA did not suppress the response of the responder lymphocytes. In contrast, the major low density lipoprotein (LDL) did not suppress lymphocytes at equivalent concentration in the induction culture, nor did LDL-exposed lymphocytes suppress responder lymphocytes. The supernatant medium from LDL-In-suppressed lymphocytes did not contain a newly synthesized or released suppressive factor. Finally, LDL-In-suppressed lymphocytes were not rescued by normal lymphocytes. Each of these observations, and previous evidence that adherent cells do not mediate the biologic effects of LDL-In, support the hypothesis that the biologic manifestations of LDL-In suppression of lymphocyte function result from a direct effect on the lymphocyte that is exposed to this lipoprotein, possibly via the previously demonstrated LDL-In receptor.     

In vivo suppression of the primary immune response by a species of low density serum lipoprotein.

An apparent subspecies of normal human serum low density lipoprotein (LDL-In) has been identified with suppressive activity for early or facilitating events of human lymphocyte mitogen and allogenic cells stimulation in vitro. This report describes the effects of in vivo administration of LDL-In on the mouse anti-SRBC immune response. Human LDL-In is not species specific and was capable of suppressing the in vivo mouse anti-sheep erythrocyte (SRBC) hemagglutination response by 88% after the administration of 500 to 600 mug LDL-In IV, whereas human serum high density lipoproteins and fibrinogen had no effect. Maximal suppression occurred only when LDL-In was injected 24 to 48 hr before antigen administration. Simultaneous or subsequent injection of LDL-In had no effect. The activity of LDL-In was influenced by antigen dose and maximal at low antigen doses. The number of splenic plaque-forming cells was also reduced indicating a suppression of the clonal expansion of primary B cells to antibody-secreting cells rather than only suppression of antibody synthesis by differentiated B cells and their progeny. These observations suggest the hypothesis that endogenous LDL-In could play an important immunoregulatory role in the maintenance of immune homeostasis and the "natural" suppression of non-productive lymphocyte proliferation.     

Regulatory serum lipoproteins: regulation of lymphocyte stimulation by a species of low density lipoprotein.

Low density lipoproteins (LDL) containing apolipoprotein B were separated from 15 fresh normal human serum pools by three independent isolation methods including sequential ultracentrifugal flotation, affinity chromatography, and polyanion precipitation. A discrete subpopulation of LDL (LDL-In) was isolated which possessed comparable inhibitory activity for PHA, PWM, and allogenic cell stimulated human lymphocytes in vitro at concentrations of 1 to 10 mug protein/1 x 10(5) lymphocytes/0.25 ml culture. LDL-In was characterized by a mean buoyant density of 1.055 g/ml in KBr, a m.w. of 2 to 3 x 10(6) daltons and a composition of 20 to 25% protein and 75 to 80% lipid with beta electrophoretic mobility. The biologic activity of LDL-In was non-cytotoxic, independent of mitogen concentration, and dependent upon the concentration of serum in the culture assay. The effect was temporally dependent requiring approximately 24 hr for induction of a stable suppressed state. Suppression was reversible with shorter periods of exposure to LDL-In. LDL-In did not inhibit lymphocytes at periods greater than 19 hr after stimulation, suggesting that LDL-In may influence metabolis events associated with the inductive phase of lymphocyte activation by lectins and allogeneic cells. LDL-In was clearly distinguishable from T lymphocyte E rosette inhibitory factor since it did not influence E rosette function of lymphocytes. The physicochemical and biologic properties of LDL-In clearly distinguish this reguloratory lipoprotein from previously described immunoregulatory factors.     

Regulation of bone marrow lymphocyte production: IV. Cells mediating the stimulation of marrow lymphocyte production by sheep red blood cells: Studies in anti-IgM-suppressed mice,athymic mice,and silica-treated mice

Some cellular requirements have been examined for the stimulation of lymphocyte production in mouse bone marrow by injected sheep red blood cells (SRBC). The increased genesis of marrow lymphocytes after a single dose of SRBC assayed radioautographically after [³H]thymidine labeling was unimpaired in the marrow of mice treated with anti-IgM antibodies from birth to eliminate B lymphocytes, and in congenitally athymic mice lacking T lymphocytes. However, pretreatment of mice with silica to depress macrophage function completely abolished the SRBC effect both on the total lymphocyte production and on the number of B and null small lymphocytes in the marrow. Comparative studies were performed on the thymus and spleen. The results demonstrate that the stimulation of marrow lymphocyte production by SRBC is mediated by a silica-sensitive mechanism, does not require B or T lymphocytes, and is independent of the humoral immune response. Thus, extrinsic agents may amplify the production of primary B cells and other lymphocytes in the bone marrow by an antigen-nonspecific mechanism, putatively mediated by macrophages.     

Effector cell activity in antibody mediated cell dependent immune lysis. II. Evidence for different populations of effector cells for different targets.

Using the adhering property of certain types of cells to glass or plastic in human peripheral blood lymphocyte preparations, two populations of effector cells can be identified in the ABCIL system, each with a selective killing directed toward a different antibody coated target. The adherent cells which are radioresistant functionally, with the morphology of macrophages, exhibit strong cytotoxicity against the antibody-coated erythroid target while lacking any killing effect toward the antibodycoated target lymphocytes. The nonadherent cells which are radiosensitive and with the morphology of small lymphocytes, selectively kill the antibody-coated lymphocyte target without possessing any cytotoxicity against the antibody-coated target erythrocytes.     

Nonspecific cytotoxic effects of antigen-transformed lymphocytes. Kinetics, cell-requirements and the role of recruitment

PPD-stimulated human peripheral blood lymphocytes have been shown to exert a nonspecific cytotoxic effect on allogeneic and xenogeneic target cells labeled with ⁵¹Cr. Chromium release induced by washed transformed lymphocytes was linear with time. At lymphocyte to target cell ratios of 120:1, significant killing could be demonstrated as early as $\text{1}\text{2}$ hr. At 8 hr, killing occurred with ratios as low as 3:1. The cytotoxic effect was related to the ability of the lymphocytes to transform to PPD, but reached an earlier peak than either DNA or RNA synthesis. Supernatants from lymphocyte cultures were not cytotoxic: instead, viable transformed cells were required. Partial removal of macrophages from the original cultures increased the cytotoxic effect.Lymphocytes could also be nonspecifically recruited to exert a cytotoxic effect by a mitogenic-like factor produced in transforming cultures. Preliminary evidence suggested that this factor acted independently of PPD and of histocompatibility antigens. These results are discussed with reference to possible amplification mechanisms for late cytotoxic effects, and to delayed hypersensitivity reactions in vivo.     

Studies on the regulation of lymphocyte reactivity by normal and activated macrophages.

To determine the potential role of macrophages as regulators of the immune response, the effect of mouse peritoneal macrophages on transforming mouse spleen lymphocytes was investigated. Mitogen and antigen stimulated lymphocyte transformation, as measured by DNA synthesis, was enhanced by all concentrations of normal macrophages tested, but only by low concentrations of activated macrophages. High concentrations of activated macrophages markedly inhibited lymphocyte transformation. This inhibition occurred whether lymphocyte DNA synthesis was measured by incorporation of [³H]TdR or of ³²P. Activated macrophages cultured with lymphocytes within 4 hr of being removed from the peritoneal cavity inhibited lymphocyte transformation. When activated macrophages were cultured alone for 24 or more hours before addition of lymphocytes, enhancement of transformation was noted. Once lymphocytes were exposed to activated macrophages, they could not be induced to undergo transformation in the presence of Con A. Whereas heat-killed activated macrophages, which appeared intact morphologically, lost their capacity to inhibit lymphocyte transformation, macrophages treated with mitomycin C to inhibit DNA synthesis retained this capacity. Syngeneic and allogeneic macrophages had similar inhibitory ability. Supernatants from cultures of many cell types (including normal or activated macrophages, lymphocytes, lymphocytes plus macrophages, and L cells) inhibited [³H]TdR incorporation by both mitogen stimulated lymphocytes and tumor cells. These studies demonstrate the capacity of macrophages to regulate lymphocyte transformation in vitro and suggest a role for these cells as regulators of cell-mediated immunity in vivo.     

Suppressor macrophages in lymphocyte proliferation of cynomolgus monkeys

The present study demonstrated the presence of cells belonging to monocyte/macrophage lineage which suppressed mitogen-induced blastogenesis of peripheral blood lymphocytes in cynomolgus monkeys. Depletion of adherent or phagocytic cells from peripheral mononuclear cells caused a substantial increase in the blastogenic response of cynomolgus monkey lymphocytes whereas the same treatment led to marked reduction rather than enhancement in human lymphocyte blastogenesis. Addition of thioglycollate-elicited peritoneal exudate adherent cells as macrophages suppressed the blastogenic response of nonadherent lymphocytes in a dose-dependent manner. The suppressive effect was observed not only in autologous but also in allogeneic macrophages to the responder lymphocytes. Treatment of macrophages with silica, carrageenan or freezing-thawing reduced their suppressive effect but there was no reduction with mitomycin C or indomethacin. No suppressive activity was detected in the cell-free supernatant of macrophages cultured in the presence or absence of mitogens for up to 4 days. From these findings, it appeared that monocyte/macrophage lineage might be responsible for the observed suppressive effect on mitogen-induced blastogenesis of cynomolgus monkey lymphocytes.     

A possible role of prostaglandins in the inhibition of natural and antibody-dependent cell-mediated cytotoxicity against tumor cells

We recently observed that certain tumor cell lines in tissue culture produced prostaglandins and that increased production occurred when the tumor cells were exposed to lymphocytes. The present experiments tested the effect of prostaglandins E₁ and E₂ on natural and antibody-dependent lymphocyte cytotoxicity against the same target cells in order to determine whether the production of prostaglandins by the tumor cells might influence the efficacy of the cellular immune response. Target cell lines T₂₄ and HCV₂₉ were labeled with ⁵¹Chromium and incubated at 37 °C for various times with lymphocytes prepared from venous blood of normal donors. Antiserum to T₂₄ and varying concentrations of prostaglandin E₁ or E₂ were added to the samples prior to incubation. In some experiments, lymphocytes or labeled target cells were preincubated with prostaglandins and then washed prior to their addition to the assay tubes. Cytotoxicity was determined by measuring the release of ⁵¹Chromium from the target cells after incubation. Both prostaglandins E₁ and E₂ inhibited natural and antibody-dependent lymphocyte cytotoxicity against the target cells. The effect appeared to represent a direct one on lymphocytes, and it was amplified by the presence of theophylline in the medium. Inhibition could be effected early on in lymphocyte/target cell interaction, and only a short exposure of lymphocytes to prostaglandins was required for the effect to be manifested. It thus appears that the production of prostaglandins by tumor cells may constitute a means by which the tumor cells subvert the effect of a cellular immune response that is directed against them.     

Functional characteristics of in vitro generated macrophages: a transient refractory state precedes reinducibility of a spatially restricted, possibly contact-dependent, cytostatic mechanism

Adherent layers of macrophages (M phi-c) generated in vitro from splenic precursors previously have been shown to inhibit proliferation of normal and neoplastic cells by mechanisms that do not involve the secretion of significant quantities of prostaglandins, peroxides, or proteases. In the current report, it is demonstrated that the effective range of the cytostatic effect of adherent M phi-c is so low that cytostasis can be circumvented by preventing the target cells from settling to the adherent layer by incubating the cultures of targets and M phi-c on a rocking platform. Despite the paucity of production of inhibitory mediators, the M phi-c do produce sufficient IL-1 to restore IL-2 production capacity to macrophage-depleted lymphocyte populations. The cytostatic activity of the M phi-c is an inducible event and remains for several days in the continuous presence of mitogen-activated lymphocytes or LPS + lymphokines. Once the activators are removed the cytostatic activity rapidly declines, reaching background levels in 24-48 hr. Maximal cytostatic activity can be reinduced but only 48 hr or longer after the primary activators were removed. A transient period in which the M phi-c are refractory to reactivation can be demonstrated to exist for 1-2 days after removal of the primary activators.     

Human immunodeficiency virus (HIV)-positive sera obtained shortly after seroconversion neutralize autologous HIV type 1 isolates on primary macrophages but not on lymphocytes

The aim of this study was to analyze the role of humoral immunity in early human immunodeficiency virus (HIV) infection. As neutralizing activities in HIV-positive sera are rarely detectable earlier than 9 to 12 months after infection using primary lymphocytes as target cells in neutralization assays, humoral immunity is generally thought not to contribute significantly to early virus control in the patients. Besides lymphocytes, cells of the monocyte/macrophage lineage are known to be important target cells for HIV in vivo during the establishment of the infection. Therefore, we studied the neutralization of early primary HIV isolates by autologous serum samples using primary macrophages as target cells in the neutralization assays. We analyzed neutralizing activities against the autologous HIV-1 isolates in 10 patients' sera taken shortly after seroconversion, both on primary macrophages and, for comparison, on lymphocytes. Viruses were isolated and expanded in primary mixed cultures containing macrophages and lymphocytes in order to avoid selection for one particular cell type. All viruses replicated to different degrees in macrophages and lymphocytes; nine had a nonsyncytium-inducing phenotype, and one was syncytium inducing. The detection of neutralizing antibodies in acute primary HIV infection depended on the target cells used. Confirming previous studies, we did not find neutralizing activities on lymphocytes at this early time point. In contrast, neutralizing activities were detectable in the same sera if primary macrophages were used as target cells. Differences in neutralizing activities on macrophages and lymphocytes were not due to different virus variants being present in the different cell systems, as gp120 sequences derived from both cell types were homogeneous. Neutralization activities on macrophages did not correlate with the amount of beta-chemokines in the sera. As affinity-purified immunoglobulin G preparations from an early patient serum also exhibited neutralization of the autologous virus isolate on primary macrophages, but not on lymphocytes, neutralization is very likely due to antibodies against viral epitopes necessary for infection of macrophages but not for infection of lymphocytes. Our data suggest that, along with cell-mediated immunity, humoral immunity may contribute to the reduction of primary viremia in the patient. This was further supported by a certain association between neutralizing antibody titers on macrophages and viral load in the patients.     

Lysozyme-induced inhibition of the lymphocyte response to mitogenic lectins

Both human lysozyme (HL) and hen egg white lysozyme (HEWL) inhibited the proliferative response of peripheral blood lymphocytes to T cell mitogens such as the lectins phytohemagglutinin and concanavalin A. This inhibition was observed both when HL or HEWL was added to the lymphocyte cultures in combination with phytohemagglutinin or concanavalin A and when lymphocytes were pretreated with either lysozyme and extensively washed prior to culture with mitogens. Under both conditions, the effects were strictly dose dependent; the lysozyme concentrations yielding maximal inhibitory effect were 5 micrograms/ml for HL and 1 microgram/ml for HEWL, while both lower and higher concentrations were less effective. Specific antilysozyme rabbit sera completely prevented the inhibitory effects of both HL and HEWL on the proliferative response of lymphocytes to phytohemagglutin or concanavalin A. Chitotriose (a lysozyme inhibitor) caused a strong reduction in the inhibitory effects of the two lysozymes on the lymphocyte response to either lectin. HL and HEWL also were found to markedly inhibit the polyclonal B cell proliferation and differentiation induced by pokeweed mitogen and T cells. A less marked inhibition was also obtained when T cells, but not B cells, were pretreated with HL or HEWL. Again, as in the experiments with T cell mitogens, the effects were dose dependent and 5 micrograms/ml HL and 1 microgram/ml HEWL proved to be the most effective concentrations. The possible mechanisms by which lysozyme inhibits the lymphocyte response to mitogenic lectins are considered and discussed. The enzymatic activity seemed to perform an essential function, as shown by the loss of effect when the heat- or trypsin-inactivated lysozymes were used and by the fact that only the enzymatically active compound, among certain semisynthetic derivatives of HEWL, inhibited the lymphocyte response to the mitogens. However, the cationic properties of the lysozyme molecule appeared to be essential too, since enzymes with a similar specificity of action showed effects similar to those observed with HL or HEWL only when they carried a strong positive charge. It is suggested that lysozyme, which is naturally secreted by monocytes and macrophages, might interact with lymphocyte surface receptor sites and participate in the complex mononuclear phagocyte-lymphocyte interactions and in the modulation of lymphocyte activation.     

Novel mechanism for Trypanosoma cruzi-induced suppression of human lymphocytes. Inhibition of IL-2 receptor expression

Co-culture of blood forms of Trypanosoma cruzi, the causative agent of Chagas' disease, with human PBMC impaired the capacity of T lymphocytes to express surface receptors for IL-2. This effect was evidenced by marked reductions in both the proportion of Tac+ cells and the density of Tac Ag on the surface of the positive cells, determined by flow cytometry. The extent of the inhibition increased with parasite concentration. Under optimal or suboptimal conditions of stimulation with either PHA or monoclonal anti-CD3, specific for an epitope of the T3-Ti human T cell Ag receptor complex, the presence of T. cruzi curtailed the capacity of T lymphocytes to proliferate and express Il-2R but did not affect IL-2 production. Furthermore, the addition of exogenous IL-2 did not restore the responsiveness of suppressed human lymphocytes but did when mouse lymphocytes were used instead. Therefore, unlike mouse lymphocytes, human lymphocyte suppression by T. cruzi did not involve deficient IL-2 production and was accompanied by impaired IL-2 utilization. Co-culture of human monocytes/macrophages with suppressive concentrations of T. cruzi increased IL-1 production, and the parasite did not decrease IL-1 secretion stimulated by a bacterial LPS. Therefore, the suppression of IL-2R expression and lymphoproliferation is not likely to have been an indirect consequence of insufficient IL-1 production due to infection of monocytes or macrophages. We have shown that suppression of human lymphocyte proliferation by T. cruzi is not caused by nutrient consumption, absorption of IL-2, lymphocyte killing, or mitogen removal by the parasite. Therefore, these results uncover a novel suppressive mechanism induced by T. cruzi, involving inhibited expression of IL-2R after lymphocyte activation and rendering T cells unable to receive the IL-2 signal required for continuation of their cell cycle and mounting effective immune responses.     

Stimulation of human peripheral blood lymphocytes by periodate, galactose oxidase, soybean agglutinin, and peanut agglutinin: differential effects of adherent cells.

Blastogenic responses of normal human peripheral lymphocytes to three distinct groups of mitogens were studied: Group I--phytohemagglutinin (PHA), concanavalin A (Con A), and pokeweed mitogen (PWM); Group II--soybean agglutinin (SBA) and peanut agglutinin (PNA); and Group III--galactose oxidase (GO) and sodium periodate (IO4-). SBA was mitogenic for human cells, and this effect was enhanced by treating the cells with neuraminidase (NA). PNA was mitogenic only after cells had been treated with NA. GO was effective before and activity was increased after lymphocytes were treated with NA. Responses to Group II and III mitogens were more variable than were those to Group I mitogens. Studies with purified T and B cells indicated that SBA and PNA were T cell mitogens, whereas IO4- and GO failed to stimulate either T or B cells. Adding macrophages back to this system indicated that they were both T cell mitogens with strict macrophage requirements. T cell responses to SBA and PNA were enhanced over responses to unfractionated cells to a degree that could not be explained simply by enrichment of the cultures with T cells. Removal of adherent cells from unfractionated cell suspensions again revealed a marked enhancement of responses to SBA and PNA, a consistent decrease in responses to IO4-, and a variable decrease in responses to GO. Similar results were found with 14C-leucine and 3H-uridine incorporation, as well as 3H-thymidine for the assessment of bastogenic response. Mechanisms responsible for these differential effects of macrophage depletion on lymphocyte responses to different groups of mitogens are yet to be determined. Either different mitogens require different lymphocyte to macrophage ratios for optimal stimulation, or some mitogens (i.e., SBA and PNA) form inhibitory complexees in the lymphocyte-macrophage mixture. In any case, variability in response to mitogenic agents in normal as well as pathologic states may be dependent on adherent cell populations, rather than on the lymphocytes themselves.     

Tumour necrosis factor-alpha and lipopolysaccharide enhance interferon-induced tryptophan degradation and pteridine synthesis in human cells

The capacity of recombinant interferon-alpha, -beta and -gamma, of bacterial lipopolysaccharide and of recombinant tumour necrosis factor-alpha to induce indoleamine 2,3-dioxygenase and synthesis of pteridines was studied in human peripheral blood mononuclear cells, human macrophages and normal dermal fibroblasts. The action of interferon-alpha and -beta on macrophages was supported by lymphocyte factors as indicated by the effect of these mediators in the absence or presence of lymphocytes. Tumour necrosis factor-alpha alone was ineffective in peripheral blood mononuclear cells and macrophages, but it significantly increased the action of all three interferon species on macrophages and fibroblasts. Lipopolysaccharide directly affected macrophages or dermal fibroblasts and enhanced the effect of interferon-gamma. However, in the presence of lymphocytes, the action of lipopolysaccharide was mediated via interferon-gamma.     

Functional activation of immune lymphocytes by antigenic stimulation in cell-mediated immunity. IV. Role of macrophage and its soluble factor in antigen-induced MIF production of immune T lymphocytes.

Histocompatibility-linked restriction of macrophage-T lymphocyte interaction in antigen-induced MIF production by sensitized lymphocytes was examined, by using combinations of inbred strain 2, strain 13, and JY-1 guinea pigs. The effective interaction of the antigen-bearing macrophages with the immune T lymphocytes was observed when the donor of the antigen-bearing macrophages and that of the immune lymphocytes shared Ia antigens of the major histocompatibility complex. Identities of B antigens and S antigens were not important for this cooperation. It was further demonstrated that the previously reported soluble factor derived from LPS-stimulated peritoneal adherent cells (macrophages) could help antigenic activation of the immune lymphocytes across the strain barrier provided a small number of macrophages (0.01%) from syngeneic strain were present. These results show that the presence of macrophages is absolutely required to present antigen to immune T lymphocytes in a genetically restricted manner and the soluble factor from macrophages appears to give a nonspecific effect on the lymphocyte activation in addition to or in collaboration with antigenic stimulation.     

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.     

In vitro enhancement of natural and antibody-dependent lymphocyte-mediated cytotoxicity against tumor target cells by interferon.

Interferon derived from virus-infected human leukocytes or fibroblasts was found to enhance spontaneous and antibody-dependent lymphocyte cytotoxicity against human target cell lines in vitro. The greater enhancement occurred with spontaneous lymphocyte cytotoxicity. Interferon exerted its effect directly on lymphocytes; no effect on target cells was seen. The mechanism of enhancement was unclear: It did not reflect antibody production or lymphocyte proliferation. Enhancement appeared to be immunologically nonspecific, but clarification of this effect awaits further study.     

Regulation of immunoglobulin production in human peripheral bood leukocytes: cellular interactions.

The intercellular influences regulating immunoglobulin (Ig) synthesis by normal human peripheral blood leukocytes (PBL) were investigated in cells stimulated by pokeweed mitogen (PWM). This system was shown to be totally T lymphocyte dependent as purified B lymphocytes (less than or equal to 1% T lymphocytes) failed to make significant amounts of Ig. No evidence was obtained for an Ig class switch as all classes of Ig (IgM, IgG, IgA) were shown to be produced in increasing amounts over a 6-day time period. T lymphocytes demonstrated maximum helper effect when mixed with equal numbers of B cells. This helper effect was mediated through the dual mechanisms of increasing the number of B lymphocytes containing cytoplasmic Ig and by increasing the maturity of these B lymphocytes as demonstrated by an increasing Ig production per B lymphocyte. When present in higher numbers, T lymphocytes were also capable of suppressing Ig production. This T-mediated suppression was first evident as a decrease in the Ig produced per B lymphocyte (decreased maturity). With maximum T suppression Ig-containing B lymphocyte numbers were also diminished. T lymphocyte help was relatively independent of macrophages (phagocytic cells) and did not require DNA synthesis for expression. Both T help and suppression were shown to cross allogeneic barriers. Immature T lymphocytes (thymocytes) were incapable of mediating either activity. Normal human PBL contain T lymphocytes campable of mediating both T help and suppression and the Ig produced by PBL was shown to be the balance of these activities. This balance probably represent the participation of distinct T lymphocyte subpopulations analogous to the T helper (Ly 1+) and T suppressor (Ly 2+, 3+) populations in the mouse.