In vitro effect of various mitogens on starfish (Asterias rubens) axial organ cells

The effects of various mitogens on axial organ (AO) cells of the sea star have been studied. Pokeweed mitogen (PWM) stimulates [³H]thymidine incorporation by the whole population of axial organ cells of the sea star. This effect occurs 24 hr after the addition of PWM and is maximal at 40 μg/ml. In contrast, no stimulation is observed when coelomocytes are treated with PWM under the same conditions. No stimulation of the whole AO cell population is observed in the presence of Con A or LPS. However, the AO cell population can be divided, on the basis of surface adherence properties, into two subpopulations, adherent and nonadherent. Con A stimulates the nonadherent cells, but not the adherent cells: The stimulating effect is maximal 24 hr after addition of Con A and at 0.2–0.5 μg/ml. In contrast, LPS stimulates the adherent but not the nonadherent cells and the stimulating effect is maximal at 24 hr and at 45 μg/ml.     

Antigen-Specific Proliferative Response of Peritoneal Exudate Lymphocytes Primed with Antigen and Bacterial Lipopolysaccharide: The Roles of Ia+ Accessory Cells and IL-2

In vitro antigen-specific proliferation was investigated in a lymphocyte population that had been taken from the peritoneal exudate cells (PEC) of C3H/HeN mice (Ia^k) primed in vivo with both bacterial lipopolysaccharide (LPS) and horse red blood cells (HRBC) and had been purified by passage through a nylon fiber column (Nfc). The proliferative response of the Nfc-passed lymphocytes primed with HRBC and LPS [T(HRBC + LPS) cells] depended on the dose of antigen in the cultures, and the response was higher than that of cells prepared from mice primed with HRBC alone [T(HRBC) cells]. No response was seen in the cells prepared from the LPS-primed mice [T(LPS) cells] or normal mice [T(N) cells]. The response of the T(HRBC) cells was abolished by previous treatment of the cells with anti-Ia^k antibody and complement (C), whereas the response of the T(HRBC + LPS) cells was retained after the same treatment, indicating that the Ia^– T(HRBC + LPS) cells can proliferate in response to antigen in spite of Ia+ accessory cell-depletion. Supernatants from the cultures of Ia^– T(HRBC + LPS) cells in the presence of HRBC showed abundant IL-2 activity, while those of Ia^– T(HRBC) cells did not. The IL-2 should be produced by the L3T4 cell population in T(HRBC + LPS) cells in response to antigen, since the previous treatment of the cells with anti-L3T4 antibody and C abrogated the production. On the other hand, the Ia^– T(HRBC + LPS) cells as well as the Ia^– T(LPS) cells could respond to IL-2 dose-dependently when recombinant IL-2 was added into the cultures, but the response of Ia^– T(HRBC) cells to IL-2 was very weak. The cell population responding to IL-2 in the T(HRBC + LPS) cells as well as T(LPS) cells must be AsGM1-positive or natural killer (NK) cells, since previous treatment of the cells with anti-AsGM1 antibody and C abrogates the response. Together these results suggest that L3T4 lymphocytes capable of producing IL-2 in response to HRBC antigen without Ia⁺ accessory cells are generated in the PEC of the mice after priming with LPS and antigen together, and the IL-2 produced by the L3T4 lymphocytes induces the proliferation of the LPS-primed AsGM1+ cells.     

Interleukin 1 secretion is not required for human macrophage support of T-cell proliferation

Interleukin 1 (IL-1) is a soluble factor secreted by stimulated monocytes (Mo) and animal macrophages (Mx). We have previously demonstrated that human Mo cultured in vitro for 1-6 days transform to Mx, and retain their ability to support concanavalin A (Con A)-driven T-cell proliferation. We have also shown that, paradoxically, these Mx do not secrete IL-1, when stimulated by endotoxin (LPS). In this study we examined two alternative hypotheses: T cells plus mitogen induce Mx IL-1 production, and human Mx deliver a second signal to T cells via a non-IL-1 mechanism. IL-1 was assayed in a mouse CD-1 thymocyte system without concanavalin A. Mo/Mx were cultured with T cells at low (2 X 10(4)/200 microliters) or high (1 X 10(5)/200 microliters) concentrations for 2 or 4 days, in the presence of Con A. Six hours prior to quantitation of proliferation, 50 microliters of supernatant was removed and assayed for IL-1. As expected both Mo and Mx enhanced T-cell proliferation eight- to tenfold. Mo secreted large amounts of IL-1; there was no demonstrable IL-1 activity present in supernatants from cultures containing either T cells and Mx, or Mx alone. Similar results were obtained by preincubating the cells (Mo, Mx, and T cells) with Con A for 12 hr and removing Con A prior to a 36-hr coculture. We examined the possibility that a small amount of IL-1 may be able to support Con A-stimulated T-cell proliferation and yet may not induce thymocyte proliferation. The highest dilutions of Mo supernatant (1:125) which supported T-cell proliferation also caused a fivefold increase in thymocyte proliferation. Supernatants from Mx failed to stimulate thymocyte proliferation or support Con A-driven T-cell proliferation. However, Mo and Mx lysates contain Il-1 activity. We conclude that human Mx support Con A-induced T-cell proliferation in the absence of IL-1 secretion. Mx may support T-cell proliferation by cell-bound IL-1 or by a non-IL-1 mechanism.     

Regulation of in vitro lymphocyte responses: I. Adjuvant effect of lipopolysaccharide (LPS) on low-zone unresponsiveness to concanavalin A

Simultaneous addition of concanavalin A (Con A) and lipopolysaccharide (LPS) to cultures of rat spleen lymphocytes resulted in a synergistic effect on DNA synthesis as measured by increased [³H]thymidine uptake after 3 days. This effect was maximal when 10 μg of LPS was added to understimulating doses of Con A (synergistic index = 14) and diminished with increasing doses of the mitogen. In contrast to increasing concentrations of serum factors, LPS was not able to unblock the nonresponse of lymphocytes stimulated with supraoptimal doses of Con A. LPS did not exert its adjuvant effect by stimulating lymphocytes with the help of soluble factors released by Con A-activated cells. Both Con A and LPS seem rather to act together on a distinct population of T-cells which can be separated on nylon columns and respond twice as much as nonseparated cells to their synergistic combination. Rat B-cells were unresponsive to stimulation with Con A and LPS added alone or simultaneously. These results help to better understand some of the mechanisms involved in the immunological enhancement observed with LPS.     

Mechanism of histamine-induced inhibition of lymphocyte response to mitogens in mice

Histamine induced, in mice, an inhibition of lymphocyte response to PHA and LPS, at molar concentrations ranging from 10^?3 to 10^?9M. This inhibition occurs as a specific interaction between histamine and T lymphocytes bearing H2-type receptors for this hormone (H + cells) and Ly 2 membrane antigens. Two features of the suppressive activity of this T-cell subpopulation were observed: (i) when histamine is added at the beginning of the culture period with PHA or LPS, it activates the suppressor activity of H + cells which act on the lymphocyte population responding to PHA and LPS; (ii) preincubation of spleen lymphocytes with histamine for 24 hr induces suppressor cells which inhibit the response to PHA, but not to LPS, of syngeneic lymphocytes in a coculture system, and which are radiosensitive. The role of PHA as a second stimulus of histamine-induced suppressor cells, and the relation between these cells and PHA or Con A-induced suppressor cells, are discussed.     

Cytotoxicity of lymphoid cells induced by Maclura pomifera (MP) lectin.

The cytotoxic activity of lymphoid cells stimulated with Maclura pomifera (MP) lectin was investigated. Spleen cells of Lewis (LEW) or Brown Norway (BN) rats induced a cell-dependent release of ⁵¹Cr from syngeneic, allogeneic, and xenogeneic erythrocytes when incubated with MP for 4–16 hr. The activity of MP differed from that of concanavalin A (Con A). MP exhibited a greater activity with spleen cells while Con A was more active when bone marrow cells were tested. Activity induced by MP required the presence of the lectin for at least 4 hr and was inhibited by melibiose, an inhibitor of MP binding. MP also stimulated phagocytosis by peritoneal macrophages of LEW rats, but phagocytosis was not responsible for the cytotoxic effect measured by ⁵¹Cr release. The ability of aggressor cells to bind MP did not correlate with their cytotoxic activity. The cytotoxic activity of spleen cells from athymic nude mice was equivalent to that of cells from euthymic littermates when stimulated with MP.     

Synergy between T cell-replacing factor and bacterial lipopolysaccharides (LPS) in the primary antibody response in vitro: a model for lipopolysaccharide adjuvant action.

Unfractionated spleen cells, B cells from normal mice, and nu/nu spleen cells respond to the addition of bacterial lipopolysaccharide (LPS) and T-cell-replacing factor (TRF) by production of plaque-forming cells (PFC) in excess of the number expected from the addition of LPS and TRF separately. This synergistic activity is dependent on the presence of the antigen, SRBC. Supernatants of both allogeneic spleen cell mixtures and spleen cells cultured with Con A are effective and synergize best at concentrations suboptimal for their ability to act as TRF alone. Culture supernatants of unstimulated normal or fractionated cell populations are ineffective. Synergy is not dependent on the presence of macrophages in the cultures. Purified LPS free from active contaminants, as well as commercially available LPS, show synergy with TRF. Synergy was seen when TRF was added at initiation of culture or 24 hr later. It is suggested that synergy is the equivalent of LPS adjuvant activity, that the role of T cells in LPS adjuvanticity is that of a conventional cooperating cell, and the LPS acts as an adjuvant by inducing B cells to become more sensitive to T cell helper factors.     

Heterogeneity of eosinophil chemotactic factors produced by splenic T cells of Schistosoma japonicum-infected mice

Spleen cells of Schistosoma japonicum-infected mice produced eosinophil chemotactic factors (ECF-Ls) upon stimulation with soluble egg antigen preparation (SEA) and Con A, while spleen cells from uninfected mice produced ECF-L upon stimulation with Con A but not with SEA. Depletion of CD4⁺ T cells, but not of CD8⁺ T cells, almost completely removed Con A-induced ECF-L production. In contrast, depletion of CD8⁺ T cells completely abolished SEA-induced ECF-L production while depletion of CD4⁺ T cells did not, indicating that CD4⁺ CD8⁻ T cells and CD4⁻CD8⁺ T cells play essential roles for the production of Con A-induced ECF-L and SEA-induced ECF-L, respectively. Con-A-induced ECF-L had a high affinity to Con A-Sepharose but not to Procion Red agarose. In contrast, SEA-induced ECF-L bound to Procion Red agarose, but not to Con A-Sepharose. A gel permission HPLC analysis revealed that the apparent molecular weight of Con A-induced ECF-L and SEA-induced ECF-L was 16 kDa and 35 kDa, respectively. Both Con A-induced ECF-L and SEA-induced ECF-L had a similar isoelectric point (pI 3.5–3.6). These results indicate that selective stimulation of either CD4⁺ or CD8⁺ T cells of S. japonicum-infected mice produces heterogeneous ECF-L.     

Inhibition of the mitogenic response to lipopolysaccharide (LPS) in mouse spleen cells by polymyxin B.

The addition of low doses of the cationic polypeptide antibiotic, polymyxin B (PB), to cultures of mouse spleen cells inhibits lipopolysaccharide-(LPS) induced DNA synthesis but not that stimulated by PPD, PHA, or Con A. Inhibition is stoichiometric; the mitogenic response is suppressed by 50% at a weight ratio of PB:LPS of 0.055 to 1. Furthermore, PB-LPS complexes have a much reduced mitogenic capacity. These complexes inhibit the mitogenic response of spleen cells to unmodified LPS but not to PPD, Con A, or PHA. The inhibitory activity of PB is less effective when added after LPS is mixed with responding cells, achieving 50% inhibition when addition is made at 4 to 6 hr. Time course experiments indicate that partial inhibition is a reflection of a lower rate of DNA synthesis. Thus, PB inhibition of LPS mitogenesis apparently occurs as a result of formation of PB-LPS complexes with reduced mitogenic capacity. Specific inhibition by the complexes of mitogenesis induced by native LPS suggests that the inactive complex may bind to B cells but is unable to trigger them.     

Modulation of T-cell functions: I. Effect of 2-mercaptoethanol and macrophages on T-cell proliferation

The in vitro effects of 2-mercaptoethanol (2-ME), macrophages (MØ), and concanavalin A (Con A) on the proliferation of normal spleen cells (NSC), MØ-depleted spleen cells (DSC), T cells, T-cell subpopulations, and B cells were assessed by [³H]thymidine incorporation. 2-ME alone was consistently shown not to be mitogenic for purified T cells; however, 2-ME enhanced the early (Days 1 and 2) Con A (2 μg/ml)-induced response of NSC, DSC, and T-cell preparations, but depressed the late response (Days 4 and 5). 2-ME alone was mitogenic for purified B-cells, as reported previously; and the 2-ME-induced B-cell response was inhibited by Con A. Preincubation of T cells with 2-ME was sufficient for enhanced Con A responsiveness; however, if 2-ME was added 24 hr after the initiation of culture, no alteration of the Con A-induced response was observed. Ly-2,3⁺ T cells were unresponsive to Con A (0.3–20 μg/ml), but the addition of 2-ME or peritoneal cells enhanced the Con A responsiveness of Ly-2,3⁺ T cells over 200-fold. Ly-1⁺ T cells responded with a similar doseresponse and kinetic profile as unselected T cells. Although Ly-1⁺ T cells responded to Con A, unlike Ly-2, 3⁺ T cells, extensive removal of MØ significantly reduced the Con A-induced responsiveness of the Ly-1⁺ T cells. The reactivities of Ly-1⁺ and Ly-2,3⁺ DSC could be reconstituted by the addition of MØ or 2-ME; however, the kinetic response of Ly-1⁺ T cells peaked on Day 2–3, and Ly-2,3⁺ T cells had a delayed response which peaked on Day 4–5. The results indicated that (i) 2-ME and/or MØ accelerate the response kinetics of T-cells to Con A; (ii) T-cell subpopulations have differential requirements for MØ and/or 2-ME in the response to Con A; (iii) T-cell subpopulations exhibit differential dose responsiveness to Con A; and (iiii) 2-ME alters Con A responsiveness by a direct effect on T cells.     

Inhibition of neurulation and interkinetic nuclear migration by concanavalin A in explanted early chick embryos.

Effects of concanavalin A (Con A) were tested in chick embryos explanted at stages 4–7 and cultured for 24 hr. Con A (12–24 μg/ml) blocked neural tube formation by inhibiting interkinetic nuclear migration, irrespective of the stage at explanation. Somites, although less numerous than controls, were almost normal in appearance. Blastodermal expansion, heart development, and blood island formation usually were unaffected. Light microscopic and autoradiographic studies showed that the application of Con A (16 μg/ml or lower) caused no obvious variations in cell morphology, mitotic activity, and uptake of [³H]thymidine and [³H]uridine. The grafting experiments showed that Con A (16 μg/ml) strongly inhibited the differentiation of Hensen's node grafts, but not their neural inducing capacity. Furthermore, the inhibitory effect of Con A was reversible, i.e., embryos retained the ability to recover from sublethal effects of Con A when, after 4–5 hr of treatment, subcultured on plain nutrient medium.     

Generation by lipopolysaccharide of a late-acting soluble suppressor of antibody synthesis.

Polyclonal stimulation of normal mouse spleen cells by lipopolysaccharide (LPS) from Salmonella typhimurium resulted in the generation of a factor which was capable of suppressing the humoral immune response in vitro. LPS effectively induced the release of the inhibitory material into the supernatants of these cultures within 24 hr. The suppressive mediator, which was similar in properties to the antigen-generated, transiently-acting soluble suppressor (TASS) reported earlier, partially abrogated (by 30–80%) the anti-sheep erythrocyte plaque-forming cell response when added to test cultures ~20 hr prior to assay for direct hemolytic plaques. Although LPS, in submitogenic doses, also was effective in depressing the in vitro hemolysin response, the inhibitory activity of residual mitogen present in the test supernatants, and that of the LPS-induced factor, were shown to be different. By use of antisera and complement treatment to selectively deplete spleen cell populations of T or B lymphocytes, it was demonstrated that B cells were essential for production of the suppressive mediator.     

Suppression of the in vitro secondary antibody response of rabbit lymphoid cells by Concanavalin A.

The effect of various concentrations of concanavalin A (Con A) on the in vitro secondary antibody response of rabbit lymph node and spleen cells to sheep red blood cells (SRBC) was studied. Complete suppression of the IgM plaque-forming cell (PFC) response of both lymph node and spleen cultures was observed when 10 mug/ml of Con A was added at the time of initiation of the cultures whereas only partial suppression was observed when 1 mug/ml of Con A was added. Moreover, marked suppression of the immune responses of both spleen and lymph node cultures was observed when 10 mug/ml of Con A was added at 24 hr after antigenic challenge and to a lesser extent when added at 48 hr. Suppression of the IgM PFC response was also detected when spleen cultures were exposed to 10 mug/ml of Con A for as little as 2 hr after antigenic challenge. However, substantial increases in DNA synthesis were observed only in those cultures which were in contact with Con A for at least 24 hr. Finally evidence is presented that the Con A-induced suppression is mediated by a soluble substance(s).     

Soluble suppressor activity of concanavalin A-activated spleen cells on B-lymphocyte colony formation in vitro.

Supernates from concanavalin A (Con A)-activated mouse spleen cell cultures suppress the formation of B-lymphocyte colonies (BLC) in soft agar culture by 30 to 95%. Con A-induced BLC suppressive culture supernates can be heated at 80 °C for 1 hr without losing activity. The BLC suppressive activity is eliminated totally by trypsin treatment and partly by treatment with β-galactosidase. Activity is unaffected by treatment with DNAse, RNAse, and α-glucosidase. By ultrafiltration the BLC suppressive factor(s) was shown to have a molecular weight greater than 300,000. These data suggest that BLC suppression is mediated by a protein-carbohydrate complex. BLC suppression was obtained when normal spleen cells were preincubated in Con A-activated supernates for only 1 hr at 37 °C. BLC suppressor activity was absent in the supernatant fluid of Con A exposed anti-θ-treated spleen cells, nonadherent spleen cells, extensively washed spleen cells, and spleen cells from nude (athymic) mice suggesting that cells responsible for Con A-induced BLC suppression are adherent, fragile cells of the T lineage. Con A-activated spleen cell supernates do not suppress colony formation in soft agar by normal mouse granulocyte-macrophage precursors, by plasmacytoma cells, T-lymphoma cells, or by carcinoma cells. However, colony formation by Abelson's murine leukemia virus transformed B-lymphoma cells was suppressed by 95% suggesting a relationship between this immature B-lymphoma line and B-lymphocyte colony-forming cells. Con A-activated spleen cell supernates do not suppress lymphocyte activation in liquid culture by phytohemagglutinin, Con A, or lipopolysaccharide. Heat-treated supernates—which inhibited BLC development by 90–95%—did not suppress the plaque formation by spleen cells immunized in vivo or in vitro by sheep red blood cells.     

Modulation of lymphocyte functions by group A streptococcal membrane

Protoplast membranes isolated from group A streptococci suppress functions of mouse B cells in vivo and in vitro. Intraperitoneal injection 24 or 72 hr (but not 12 hr) before collection of lymphoid cells results in a selective decrease in the mitogenic response of bone marrow cells to dextran sulfate (DS). The response of bone marrow cells to lipopolysaccharide (LPS), and spleen cells to both DS and LPS, is unaltered. In vitro exposure of lymphocytes to membranes concomitantly with mitogen reduces the response to both DS and LPS, however, the DS response is more susceptible to low doses of membrane. Suppression of the response to DS in vitro is not mediated by cells bearing Thy 1.2 antigen. Neither the phytohemagglutinin (PHA)-responsive cells nor the adherent cells participate in suppression of the LPS response in vitro. In contrast to the suppression of B-cell functions neither the PHA nor concanavalin A (Con A) response of mouse bone marrow, spleen, or thymus cells is altered by streptococcal protoplast membranes injected 24 hr before collection of cells. In vitro exposure of spleen cells to a limited range of concentrations of membrane results in an enhanced proliferative response of spleen cells stimulated by suboptimal doses of PHA. This synergism is not mediated by the adherent cells. Addition of membranes to spleen cell cultures in vitro has no effect upon the response of spleen cells to suboptimal doses of Con A or to optimal doses of either Con A or PHA. Higher concentrations of membranes reduce the proliferative response of both control and mitogen-stimulated cells. This nonselective suppression by high doses of membranes is not due to toxicity. Delayed hypersensitivity to sheep erythrocytes is potentiated by injection of membranes. These studies suggest that streptococcal membranes preferentially suppress the immature B cells and enhance certain T-cell functions.     

Some Mechanisms of Disturbances and Recovery of T-Lymphocyte Migratory Properties In Irradiated Mice

Abstract Migration of ⁵¹Cr-labelled T cells from irradiated mice into lymph nodes of syngeneic unirradiated recipients decreased in a dose-dependent fashion. Influx of labelled T cells between 4 and 24 hr after injection (secondary migration) is more radiosensitive than lymph-node migration of T cells in the first 4 hr (primary migration). Treatment of T cells from irradiated mice in vitro with Con A or with trypsin does not enhance radiation-induced alteration of their migratory properties, but irradiation enhances the effects of Con A and trypsin on T-cell migration. Recovery of primary migration of irradiated T cells is completed 3 months after irradiation; it is probably caused by T-cell renewal. the defect of T-cell secondary migration is more stable: it remains 6 months after irradiation in a dose of 4 Gy. Post-irradiation defects of the T-cell differentiation process as a cause of long-lasting alteration of T-cell secondary migration are discussed.     

Inhibition by specific monosaccharides of interleukin 2-induced thymocyte proliferation

When rat thymocytes are cultured for 3 days in serum-free medium and are stimulated to divide by interleukin 2 (IL 2), concanavalin A, or sodium periodate oxidation, addition to the medium of 10–25 mMd-ribose, 2-deoxy-d-ribose, or N-acetyl-d-galactosamine inhibits by 40% or more the incorporation of [³H]thymidine. d-ribose and lectin-free IL 2 generated from sodium periodate oxidation of rat spleen cells were used to study the characteristics of this inhibition and to test possible mechanisms of inhibition. Viability of thymocytes cultured with d-ribose is similar to that of cells cultured without this sugar. In order to be inhibitory, d-ribose has to be added to the cultures within the first 24 hr, and the inhibition can be prevented if the sugar is removed 18–24 hr after the start of culture. d-Ribose does not block the absorption of IL 2 by unstimulated rat thymocytes or by concanavalin A-generated thymic or splenic blast cells. When thymocytes are cultured with d-ribose for 24 hr, inactivated with mitomycin C, and then cultured for 3 days with fresh mitogenically stimulated cells, [³H]thymidine incorporation into the latter is not altered. This suggests that the sugar does not generate suppressor cells or suppressor supernates. d-Ribose does not appear to be a general metabolic inhibitor since [³H]leucine incorporation into thymocyte proteins and the release of [³H]leucine into medium after a 2-hr. [³H]leucine pulse are not altered by d-ribose. Trivial or artifactual effects (nonspecific cytotoxicity, changes in thymidine transport, or changes in isotonicity of the culture medium) cannot explain the inhibition. A hypothetical mechanism of inhibition is discussed.     

Role of lipomodulin, a phospholipase inhibitory protein, in immunoregulation by thymocytes

The treatment of murine thymocytes with anti-lipomodulin antibody during Con A stimulation causes selective loss of suppressor activity, but not of helper activity on PFC assay, when co-cultured with T cell-depleted spleen cells. Interaction of the antibody with responder cells in thymocyte culture were necessary in the early stage rather than in the later stage of lymphocyte activation by Con A, which suggests that anti-lipomodulin antibody acts in the stage of suppressor T cells generation. When thymocytes were cultured with purified lipomodulin for 48 hr, suppressor activity was induced. Lipomodulin as detected by radioimmunoassay was found to be released from T cells with the phenotype of I-J+, Lyt-1-, Lyt-2+. The immunoprecipitates from the media of Con A-stimulated thymocyte with anti-I-Kk antibody and anti-lipomodulin antibody were analyzed on SDS-gel electrophoresis. I-J products had m.w. 36,000 and 24,000, whereas lipomodulin had m.w. 36,000, 24,000, and 15,000. Because anti-I-Jk antibody could precipitate 125I-labeled lipomodulin purified from rabbit neutrophils, these results suggest that lipomodulin is a product of I-J genes that induces suppressor T cells.     

Effect of protease inhibitors on mitogen stimulation of hamster lymphoid cells

Hamster lymph node and spleen cells can be stimulated to incorporate tritiated thymidine ([³H]TdR) in vitro under serum-free conditions by the proteases trypsin and chymotrypsin. Under similar conditions, thymocytes could be stimulated by concanavalin A (ConA) but not lipopolysaccharide (LPS) or the proteases. The subpopulation of cells responding to the proteases correlated with the cells responding to LPS on fractionation of spleen and lymph node cells on discontinuous bovine serum albumin (BSA) gradients or on nylon-wool columns. The stimulation induced by trypsin was completely blocked by soybean trypsin inhibitor (SBTI) while that induced by chymotrypsin was only partially blocked. The inhibition by SBTI of protease activation was not effective when added 24 h after initiation of stimulation. On the other hand, addition of clarified isologous serum to protease activated cultures after 24 h still lead to greater than 50% inhibition of [³H]TdR incorporation.     

Role of porin of Shigella dysenteriae type 1 in modulation of lipopolysaccharide mediated nitric oxide and interleukin-1 release by murine peritoneal macrophages

The ability of Shigella dysenteriae type 1 porin to induce the release of nitric oxide (NO) and interleukin-1 (IL-1) from peritoneal macrophages of mouse and to regulate lipopolysaccharide (LPS) and gamma interferon (IFN-gamma) mediated release of the two proinflammatory mediators was investigated. Porin released nitrite when added to macrophage cultures. A maximum of 3.2-fold nitrite release by macrophages was observed with 100 ng ml(-1) of porin. The nitrite release of LPS was enhanced significantly by lower concentrations of porin, whereas the effect of IFN-gamma was enhanced by porin at higher concentrations. Polysaccharide (PS) moiety of LPS stimulated the nitrite release of elicited macrophages by 1.6-fold compared to untreated control. It also enhanced the stimulatory effect of 1 and 10 ng ml(-1) of porin by 1.3-fold. Lipid A (LPA) moiety of LPS did not release nitrite, nor did it increase the porin mediated nitrite production. Porin treated 24 h old macrophage culture supernatants were applied for ConA activated thymocyte proliferation as a measure for determination of IL-1 release. Sixty percent depletion of thymocyte proliferation was observed when the porin treated macrophage supernatants were absorbed with anti-IL-1 antibody. A maximum of 5.5-fold increase of thymocyte proliferation over control was found with 1 and 10 ng ml(-1) of porin. One or 10 ng ml(-1) of porin and LPS augmented the thymocyte growth, 1.5-fold beyond that obtained by porin and 1.8-/1. 7-fold more than that obtained by LPS, alone. Similarly, porin and IFN-gamma co-stimulated the cell growth also. PS enhanced the thymocyte proliferation by 5-fold. It also enhanced the thymocyte growth by co-stimulating 1.4-fold the effect observed by 1 or 10 ng ml(-1) of porin alone. LPA could not participate in the cell proliferating activity nor did it enhance the stimulatory effect of porin. Therefore, both nitrite release and thymocyte proliferation by LPS could be substituted by PS only. The tight association of the two bacterial outer membrane components, porin and LPS, could be a necessary co-signal for boosting the release of the two proinflammatory mediators, namely NO and IL-1, which may be associated with the inflammatory response of the colon during Shigella invasion.