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.     

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.     

Fluorescence-activated cell sorting of human T and B lymphocytes. II. Identification of the cell type responsible for interferon production and cell proliferation in response to mitogens

We have employed the fluorescence-activated cell sorter to separate pure viable preparations of human T and enriched B lymphocytes. Using such preparations, we have demonstrated that both human T and B cells can respond to PHA and PWM in vitro in the presence of macrophages with proliferation and the production of interferon, a mediator of cellular immunity. However, selective T cell interferon production and proliferative response can be assessed at 3 days in culture; B cell interferon production and proliferative response is delayed to 5 and 7 days. T cells or T cell products are ineffective in inducing or accelerating B cell interferon or proliferative response at 3 days. The use of 3-day T cell interferon production as a new technique for the assessment of T cell effector function and competence is suggested.     

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.     

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.     

Influenza virus-induced interferon production in mouse spleen cell culture: T cells as the main producer.

Interferon production by spleen cells from unimmunized C3H mice challenged in vitro with influenza virus AO/PR8 was investigated. Glass-nonadherent cells (lymphocytes) produced significant levels of interferon, although cocultivation of glass-adherent macrophages was needed for optimal production. Treatment of the cells with antithymocyte serum and complement markedly reduced the interferon production. When glass-nonadherent cells were fractionated on a nylon wool column, the T-cell-enriched fraction consistently produced more interferon than the B-cell-enriched fraction. It is concluded that T cells are an important producer of interferon in spleen cell cultures from normal mice upon challenge with influenza virus, although non-T cells (macrophages and B cells) also may produce interferon under suitable conditions.     

Induction of interferon production in mouse spleen cell cultures by corynebacterium parvum.

Spleen cells of CS7BL/6 mice produced considerable amounts of interferon (IF) in vitro when tested 5 to 20 days after injection of killed Corynebacterium parvum. Interferon was also produced when C. parvum was added in vitro to spleen cell cultures of previously untreated mice. High levels were detected after 1 day of culture with some increment during subsequent days. In a number of experiments IF was also produced in untreated control cultures but only after prolonged cultivation and not after 1 day. The highest levels of IF were usually obtained when spleen cells of C. parvum-treated mice were challenged with additional C. parvum in vitro. The IF induced by C. parvum shared certain physicochemical properties with a tested immune IF and was not neutralized by an antiserum raised against a type I IF. Spleen cells of nu/nu mice and spleen cells treated by anti-θ serum plus complement did not differ from their respective controls, indicating that production of IF did not require mature T lymphocytes. Removal of B lymphocytes by nylon wool columns abolished the capacity of spleen cells to produce IF. When spleen cells were freed of adherent cells by the use of plastic surfaces, they no longer produced IF. Peritoneal exudate macrophages (PEC), which by themselves did not produce IF, in small numbers reconstituted nonadherent spleen cells. Nylon column-treated spleen cells, however, could not be restored by PEC. It is concluded that IF upon challenge with C. parvum is produced by B lymphocytes and requires the help of macrophages.     

Generation of lipopolysaccharide-induced interferon in spleen cell cultures

Incubation of murine spleen-cell cultures with lipopolysaccharide (LPS) induces interferon (IF) production. Maximal IF levels are obtained after incubation with 100 g/ml for 10 h. Two inbred mouse strains differing in their ability to generate LPS-induced IF in spleen-cell cultures were used: C3H/eB, which generates high levels of IF (about 60 units/ml), and C3H/HeJ, which fails to generate detectable quantities of IF. In a genetic analysis these strains were hybridized and IF production was determined in spleen-cell cultures from F₁ and F₂ generations, and from backcrosses of F₁ hybrids to parent strains. The results indicate that, in parent strains, a single dominant autosomal gene is responsible for differences in IF production in spleen cultures. LPS-induced IF in spleen-cell cultures resists pH 2 for as long as 48 h, but is labile to heating at 56° C for 30 min. Both macrophages and lymphocytes must be present in cultures for generation of LPS-induced IF. By using mixed cultures of macrophages and lymphocytes from C3H/eB and C3H/HeJ mice, it was shown that macrophages have to interact directly with LPS to enable IF production in the cultures.     

The in vitro detection of antigen sensitivity in contact dermatitis by lymphocyte transformation.

Contact sensitivity induced in rabbits by the topical application of 1-chloro-2,4-dinitrobenzene (DNCB) was evaluated by the in vitro lymphocyte transformation response. The antigen employed to stimulate cultures was a preparation of DNCB conjugated homologous lymphocytes. This antigen preparation specifically stimulated blood lymphocytes from DNCB sensitive animals to transform in vitro. The kinetics of the primary immune response were determined by antigen mediated lymphocyte transformation in rabbits percutaneously sensitized with DNCB. The peak response was reached 12 days following initial exposure to DNCB. Sensitivity decreased but remained at detectable levels through 57 days of the primary response. Skin testing the animals late in the primary response stimulated an increase in the number of circulating sensitive lymphocytes. Serum proteins, conjugated with DNCB, were not suitable antigens for the in vitro detection of contact sensitivity.     

Lymphoid cell kinetics in guinea pigs infected with Trichostrongylus colubriformis: tritiated thymidine uptake in gut and allied lymphoid tissue, humoral IgE and hemagglutinating antibody responses, delayed hypersensitivity reactions, and in vitro lymphocyte transformations during primary infections

The kinetics of the lymphocyte responses of Trichostrongylus colubriformis-infected and normal guinea pigs were measured by the in vivo uptake of tritiated thymidine either as dpm ³H/mg tissue or as the percentage change in [³H] -labeled lymphoblasts in autoradiographs of tissue impression smears and sections. The lymphoid response was predominantly a local one centering on the infected area of the small intestine. The greatest lymphocyte reactions as assessed by counts of labeled lymphoblasts occurred in the Peyer's patches and mesenteric lymph nodes where the peak responses took place 11 and 6 days after infection, respectively. The local nature of the responses was exemplified by the fact that the mesenteric lymph nodes of the anterior small intestine showed a peak response on the sixth day but the response from the posterior small intestine peaked 7 days later. A similar but less dramatic relationship existed among the Peyer's patches. In addition no labeled lymphoblast response was elicited in the inguinal lymph nodes or cecal lymphoid patches throughout the infection and the first increased responsiveness of the spleen did not take place until after Day 13, by which time the lymphoid proliferations associated with the infected intestine had subsided. Initially, the spleen showed a marked depletion of labeled blast cells during the first 7 days of the infection. This was taken as indicating at the time the infection was being established the export of cells capable of transformation in response to parasite antigen. This was supported by the observation that large numbers of phytohemagglutinin responsive lymphocytes were found in the peripheral circulation at this time. The in vitro responsiveness of peripheral lymphocytes to T. colubriformis antigen was also studied. Positive lymphocyte transformations first occurred 6 days after infection but thereafter declined to the normal level by Day 13; the peak transformation ratio was found 25 days after infection but by Day 38 it had declined to a low but persistently positive level. There was a correlation between the circulation of specifically sensitized cells, probably of thymic origin, IgE antibody titers, and the development of positive dermal delayed hypersensitivity reactions in infected guinea pigs, suggesting a close relationship among these three immunological phenomena.All lymphoblast responses in Peyer's patches, mesenteric lymph nodes, and lamina propria of the intestine were completed before the immune elimination of the parasite commenced 10 days after infection. During the first 10 days of infection specifically sensitized lymphocytes appeared and disappeared from the circulation. The loss of circulating sensitized lymphocytes at the time immune elimination of the parasite was taking place in the gut suggested that the sensitized cells were “homing-in” on the local area of infection. After the immune elimination of the parasite had commenced, the level of sensitized lymphocytes and IgE antibodies then increased rapidly in the blood. Evidence from the kinetics of the hemagglutinating antibodies indicated that stage specific antigens occur in T. colubriformis.     

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.     

Serum of rabbits infected with Treponema pallidum (Nichols) inhibits in vitro transformation of normal rabbit lymphocytes.

Serum collected from outbred male New Zealand white rabbits infected intratesticularly with Treponema pallidum (Nichols) was assayed for ability to alter transformation of normal rabbit peripheral blood lymphocytes (PBL) in vitro. Sera collected from 25 infected rabbits inhibited [³H]thymidine incorporation by normal rabbit PBL stimulated with concanavalin A (Con A, 16μg/ml), relative to PBL cultured in normal rabbit serum (NRS). Maximal inhibitory activity was detected in serum collected at the time of peak orchitis. The degree of inhibition was related to the concentration of syphilitic serum in PBL cultures. Inhibition of Con A stimulation was reversed by increased mitogen concentration. Sera which depressed Con A stimulation also depressed lymphocyte transformation induced by oxidation with sodium m-periodate (NaIO₄). Cytotoxic activity was detected in occasional sera. All sera were heat inactivated at 56 °C for 30 min prior to testing. Both freshly collected sera and sera stored at ?70 °C significantly inhibited PBL transformation. These results suggested that serum of syphilitic rabbits contains one or more inhibitors of in vitro lymphocyte transformation.     

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.     

Effects of weak laser radiation (632.8 nm) on isolated mouse immune cells

The dose dependence of in vitro effects of low-intensity radiation of a He-Ne laser (632.8 nm, 0.2 mW/cm²) on the functional activity of peritoneal macrophages and lymphocytes of mouse spleen was studied. The exposure of isolated cells was varied from 5 to 180 s. If the exposure did not exceed 60 s, stimulation of secretory activity was observed: increased production of interleukin 2, interferon γ, and interleukin 6 in lymphocytes; increased production of tumor necrosis factor α, nitric oxide, and interleukin 6 in macrophages; and enhanced activity of natural killer cells. A longer exposure (up to 180 s) either had no effect on the synthesis of certain cytokines (interleukin 2 in lymphocytes and interleukin 6 in macrophages) or inhibited it, which was expressed in decreased production of interleukin 6 and interferon γ in lymphocytes and nitric oxide in macrophages, as well as in suppression of the activity of natural killer cells. Conversely, the production of interleukin 3 decreased after a short-term exposure but increased after 180-s irradiation. The high sensitivity of cells to extremely weak laser light also manifested itself as a considerable increase in expression of the inducible heat shock protein 70; this effect was observed at all doses studied, including the 5-s exposure. In contrast, expression of the heat shock protein 90 slightly decreased after irradiation of cells with laser light.     

Induction of macrophage-mediated cytolysis of neoplastic cells by mycoplasmas

Unexpected cytolysis was encountered when nonactivated murine peritoneal macrophages were cultured with [³H]TdR-prelabeled syngeneic or allogeneic tumor cells at a 10:1 ratio. The level of specific cytolysis reached 70% within 48 hr of cocultivation. Similar killing was observed whether the macrophages were derived from untreated, thioglycollate-treated, or germ-free mice. Cytolytic activity was also demonstrated when bone marrow-derived or peritoneal macrophages from 9- and 5-day in vitro cultures, respectively, were employed rather than freshly harvested peritoneal macrophages. Thus, the macrophage-mediated killing was neither the result of in vivo preactivation nor a consequence of the presence of lymphocytes in the assay. Moreover, macrophages derived from different strains caused similar effects. Our study revealed that the neoplastic target cell cultures susceptible to cytolysis by nonactivated macrophages were contaminated with mycoplasma. A mycoplasma was isolated from the supernatant of a culture of the A9HT fibrosarcoma line, identified as Mycoplasma orale, and cultivated. Addition of viable mycoplasma from that isolate to mixed cultures of thioglycollate-elicited macrophages and [³H]TdR-prelabeled mycoplasma-free target cells resulted in specific cytolysis of transformed A9 cells, but not of normal mouse fibroblasts. The level of macrophage-dependent cytolysis correlated with the number of viable mycoplasma cells added and was higher than that attained by activation with LPS at optimal concentration. Similar specific cytolysis was observed with heat-killed mycoplasmas. Our results demonstrate that mycoplasmas may cause selective macrophage-mediated cytolysis of neoplastic but not of normal target cells, perhaps via activation of the macrophages. It is suggested that undetected infection of experimental systems by mycoplasmas may account for some reports on lysis of neoplastic cells by nonactivated macrophages.     

Leishmania tropica: pathogenicity and in vitro macrophage function in strains of inbred mice.

Of seven strains of inbred mice and one hybrid that were infected intracutaneously with 5, 10, or 20 × 10⁶ active promastigotes of Leishmania tropica major, two strains (CBA/Ca and C₃H/He) recovered from the infection and their lesions healed within 3 to 5 months. The other strains, with the possible exception of C57B1/6 animals, remained infected, carrying large cutaneous ulcers throughout their lives. These included DBA/2, A/Jax, Balb/c, athymic nude mice of Balb/c origin (nu/nu) and the heterozygote Balb/c (nu⁺). The responses of C57B1/6 animals were of intermediate type with a tendency toward nonhealing at higher doses of the parasite. The cutaneous infection of athymic nude mice invariably gave rise to fulminating visceral infections and death. This condition was never observed in the other strains tested. Concanavalin A (Con A)-stimulated syngeneic or allogeneic lymphocytes of intact mice activated peritoneal macrophages of both healer and nonhealer mice, resulting in complete destruction of phagocytosed L. enriettii within 24 to 48 hr. The destruction of ingested L. tropica was confined to macrophages of healer mice and required 72 to 96 hr to reach completion. However, removal of Con A-stimulated lymphocytes from macrophage cultures and regular pulsing of the cells with a lymphokine-rich supernatant produced a state of sustained activation, resulting in destruction of L. tropica inside macrophages of both healer and nonhealer mice. The ability of Con A-stimulated lymphocytes of nonhealer animals to induce effective levels of activation in healer macrophages on one hand, and eventual destruction of L. tropica in macrophages of nonhealer mice under condition of sustained activation on the other, had indicated that so far as the in vitro situation is concerned, there is no inherent defect in lymphocytes or macrophages of nonhealer animals, although the threshold of activation necessary for killing of the parasite seems to be higher for cells of nonhealer origin.     

Macrophage-lymphocyte clusters in the immune response to soluble protein antigen in vitro: III. DNA synthesis of lymphocytes in clusters

The lymphocytes which engage in DNA synthesis during the in vitro immune response to PPD (purified protein derivative of tuberculin) were studied by scintillation counting and in autoradiographs prepared from cultures of macrophages and immune T-lymphocyte-enriched lymphocytes. The lymphocytes in these cultures were located in three compartments: lymphocytes in macrophage-lymphocyte clusters, lymphocytes attached to macrophages but not involved in clusters, and not macrophage-attached lymphocytes. One of the cluster cells, the central lymphocyte, which is attached directly to the macrophage, was identified as the only DNA-synthesizing lymphocyte in the cluster early in the culture period. In cultures extended beyond 20 hr the increase in percentage of DNA-synthesizing lymphocytes in the cluster and macrophage-attached compartments exceeded the increase in the compartment of not macrophage-attached lymphocytes. The total amount of radiolabeled thymidine incorporated into lymphocytes in a blast transformation assay was directly proportional to the number of macrophage-lymphocyte clusters produced by the same lymphocytes in a cluster assay.     

Chicken Harder's gland: evidence for a relatively pure bursa-dependent lymphoid cell population

Theophylline, caffeine, and dibutyryl cAMP, agents that elevate intracellular levels of cyclic AMP, were found to inhibit cytotoxin elaboration by PHA-stimulated human lymphocytes. Cytotoxins in diluted supernatants from 3-day lymphocyte cultures were assayed by ⁵¹Cr release from L cells. Addition of the agents to the lymphocyte cultures inhibited cytotoxin elaboration 70–90% at 10^?3M and 20–50% at 10^?5M. In addition, it was found that the inhibition is reversible and occurs at a step other than the initial mitogen triggering.The inhibition of cytotoxin elaboration by these agents correlates strikingly with their inhibition of lymphocyte-mediated target cell lysis. The results are consistent with the hypothesis that cytotoxin is the mediator of target cell killing by lymphocytes.     

The nature of the suppressive effect of interferon and interferon inducers on the in vitro immune response

Viral-induced interferon inhibition of the primary in vitro plaque-formong cell (PFC) response in the mouse (C57B1/6) involves a dynamic relationship between the nature of the antigen, the concentration of interferon added to antigen-stimulated cultures, and the time of addition of interferon relative to antigen addition. The PFC response to a thymus-dependent antigen (sheep red blood cells) was more easily suppressed by viral-induced interferon than was that to a thymus-independent antigen (E. coli 0127 LPS), both in terms of inhibitory concentrations of interferon and the time at which the interferon could be added to cultures after antigen and still inhibit the PFC response. These differential effects of interferon could be related to the difference in cellular requirements (B and T lymphocytes) of the two antigens. Interferon was effective in inhibiting the in vitro PFC response of antigen-primed spleen cells, indicating that it can block the response of memory lymphocytes. By using interferon inducers as inhibitors of the in vitro PFC response, it was possible to show that at least two antigenically distinct interferons may be involved in suppressing the immune response. It is known that one type of interferon is induced by virus and synthetic double-stranded polyribonucleotides. The other type is stimulated by antigen and T cell mitogens. A model is proposed to explain the nature of these interferon inhibitory effects in terms of mediation of immune suppressor cell effects.     

In Vitro Analysis of the Anti-Inflammatory Effect of Inhomogeneous Static Magnetic Field-Exposure on Human Macrophages and Lymphocytes

The effect of inhomogeneous static magnetic field (SMF)-exposure on the production of different cytokines from human peripheral blood mononuclear cells (PMBC), i.e., lymphocytes and macrophages, was tested in vitro. Some cultures were activated with lipopolysaccharide (LPS) at time point −3 h and were either left alone (positive control) or exposed to SMF continuously from 0 until 6, 18, or 24 h. The secretion of interleukin IL-6, IL-8, tumor necrosis factor TNF-α, and IL-10 was tested by ELISA. SMF-exposure caused visible morphological changes on macrophages as well as on lymphocytes, and also seemed to be toxic to lymphocytes ([36.58; 41.52]%, 0.308≤p≤0.444), but not to macrophages (<1.43%, p≥0.987). Analysis of concentrations showed a significantly reduced production of pro-inflammatory cytokines IL-6, IL-8, and TNF-α from macrophages compared to negative control ([56.78; 87.52]%, p = 0.031) and IL-6 compared to positive control ([45.15; 56.03]%, p = 0.035). The production of anti-inflammatory cytokine IL-10 from macrophages and from lymphocytes was enhanced compared to negative control, significantly from lymphocytes ([−183.62; −28.75]%, p = 0.042). The secretion of IL-6 from lymphocytes was significantly decreased compared to positive control ([−115.15; −26.84]%, p = 0.039). This massive in vitro evidence supports the hypotheses that SMF-exposure (i) is harmful to lymphocytes in itself, (ii) suppresses the release of pro-inflammatory cytokines IL-6, IL-8, and TNF-α, and (iii) assists the production of anti-inflammatory cytokine IL-10; thus providing a background mechanism of the earlier in vivo demonstrated anti-inflammatory effects of SMF-exposure.