Direct evidence for sialic acid oxidation in periodate-induced lymphocyte proliferation.

Normal mouse spleen cells treated with periodate were stimulated to undergo blastogenesis. In contrast spleen cells from nude mice did not respond to periodate. Such a treatment of normal and nude spleen cells led to the oxidation of the cell surface sialic acid residues with formation of N-AN8. Prior treatment with neuraminidase of normal spleen cells greatly impaired their capacity to respond to periodate activation with a decrease in the amount of N-AN8 formed.     

The kinetics of suppression of proliferation of oxidized murine lymphoid cells by sodium borohydride reduction.

Murine splenic lymphoid cells are stimulated to proliferate following mild oxidation with sodium periodate. To assess the class of cells responding, we used periodate treatment alone or in association with concanavalin A, a T-cell mitogen, or lipopolysaccharide (LPS), primarily a B-cell mitogen. Brief periodate treatment followed by culturing with concanavalin A gave no additive proliferative response to that seen using concanavalin A alone, while culturing periodate-treated cells with LPS gave approximately an additive response. Furthermore, periodate failed to stimulate spleen cells from neonatally thymectomized mice while LPS produced significant stimulation of proliferation, suggesting that periodate is stimulating a class of T lymphoid cells or a subpopulation of T cells. Studies were performed to determine an optimal concentration of borohydride which would suppress proliferation in lymphoid cells initially oxidized with periodate. It was observed that 2 mM borohydride would suppress proliferation of oxidized cells yet permit a normal response of these cells to another T-cell mitogen, concanavalin A. Higher concentrations of borohydride, from 3 to 5 mM, would also suppress proliferation of oxidized cells but would interfere with the ability of these cells to respond to concanavalin A, perhaps due to cell damage. Studies were performed to determine when it was possible to suppress periodate-induced mitogenesis by reducing with borohydride at various times after the initial oxidation. It was observed that 2 mM borohydride treatment could suppress stimulation through 8 hr after the original periodate oxidation and that from 12 hr through 20 hr after the initial periodate oxidation, borohydride was incapable of inhibiting proliferation. Additional studies demonstrate that optimal mitogenesis induced by periodate or concanavalin A is contingent upon a serum factor.     

Reversal of murine alveolar macrophage-mediated suppression of plaque-forming cell response by sodium periodate

Murine alveolar macrophages (AM) have been shown to suppress the in vitro plaque-forming cell (PFC) response of spleen cells previously primed with sheep erythrocytes (SRBC) in a dose-dependent manner. Mild oxidation of cell membranes on viable AM with sodium periodate resulted in total abrogation of AM-mediated suppression of the PFC response, while periodate treatment of spleen cells resulted only in partial reduction of the suppression. Pretreatment of AM with sodium periodate followed by addition of the aldehyde blocking agent, hydroxylamine, resulted in restoration of the PFC-suppressing activity of AM. Periodate treatment of AM also resulted in significantly increased macrophage-T-cell binding and cluster formation. These observations suggest that the generation of aldehyde moieties on AM membrane sialoglycoconjugates promotes positive macrophage-lymphocyte interactions, resulting in abrogation of AM-mediated suppression of the PFC response.     

Mechanism of lymphocyte activation by periodic acids. Blastogenesis and induction of immunomodulator populations]

Mild periodate treatment is mitogenic for T lymphocytes. With murine spleen cells periodate oxidation is effective between C8 and C9 on sialyl acid residues. With human blood lymphocytes this oxidation occurs between C7 and C8 of these residues. In vitro immune response is inhibited by periodate treatment. Activation of an immunosuppressive T lymphocyte population is obtained. Similar results are performed with human blood lymphocytes.     

Induction of lymphocyte cytotoxicity by modification of the effector or target cells with periodate or with neuraminidase and galactose oxidase.

Treatment of mouse spleen cells with periodate (NaIO4) or with neuraminidase and galactose oxidase (NAGO) induces blastogenesis and renders the cells cytotoxic to mastocytoma (P815) target cells. Treatment of target cells (P815 cells and turkey erythrocytes) with NaIO4 or with NAGO renders them susceptible to cytolysis by untreated mouse spleen cells. The cytotoxicity induced by NaIO4 is reduced upon reacting the NaIO4-treated, effector or target cells with borohydride or hydroxylamine. Thus the formation of free surface aldehydes on either the effector or target cell induced a cytotoxic effect. It is postulated that cross-linkage via a Schiff base between effector and target cell initiates the cytotoxic effect. Cytotoxicity induced by NaIO4 or NAGO is immunologically nonspecific and is independent of major antigenic differences between effector and target cells. Phagocytic cells are not involved in NaIO4-or NAGO-induced cytotoxicity toward P815 target cells.     

Generation of cytolytic T lymphocytes in vitro. X. Induction of primary and secondary CTL responses by the mitogen sodium periodate.

Short-term (15 min) sodium periodate (NaIO4) treatment of mouse spleen cells previously primed in vivo or in vitro against alloantigens induced the formation of secondary (2 degree) cytolytic T lymphocytes (CTL) specific for the priming antigens. CTL formation was readily demonstrable within 24 hr after treatment.This early CTL response occurred equally well in the presence or absence of cytosine arabinoside (Ara C), indicating that NaIO4 could induce CTL independently of DNA synthesis. Forty-eight hours after periodate treatment, the lytic activity was similar to that observed in parallel cultures stimulated with irradiated allogeneic spleen cells, although the peak activity was reached earlier (day 4) and was somewhat lower than that induced by alloantigen. The addition of irradiated NaIO4-treated unprimed syngeneic spleen cells to cultures of untreated alloimmune spleen cells also led to CTL formation, which suggests an indirect mechanism of activation. In contrast to alloimmune spleen cells, normal spleen cells treated with NaIO4 developed only very low levels of cytotoxicity after 4 days of incubation. However, in the presence of PHA, such cells were capable of lysing syngeneic and allogeneic target cells.     

Epiderstatin and Its Related Glutarimide Antibiotics Inhibit the Cell Growth Induced by Mitogen Stimulation

To investigate the immunosuppressive effects of glutarimide antibiotics including a new antibiotic named epiderstatin, we tested these antibiotics for inhibition of the blastogenesis of mouse spleen cells induced by mitogen stimulation (concanavalin A or lipopolysaccharide). The inhibitory activity was measured by colorimetric MTT (3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyl tetrazolium bromide) assay. Among the glutarimide antibiotics tested, epiderstatin and acetoxycycloheximide especially strongly inhibited the blastogenesis of mouse spleen cells induced by concanavalin A and lipopolysaccharide, however, selectivity between T and B lymphocytes was not observed.     

The effects of sodium metaperiodate on T and B lymphocytes.

The differential mitogenic response of T and B lymphocytes to sodium metaperiodate has been investigated. It was found that periodate treatment leads to lymphocyte stimulation in spleen cells from Balb/c mice but not in spleen cells from the congenitally athymic nu/nu mice. In addition, treatment of Balb/c spleen cells with anti-θ serum plus complement lowers the mitogenic response to periodate and to concanavalin A without affecting the response to lipopolysaccharide. These results suggest a requirement for the presence of T lymphocytes in the initiation of a response to periodate. Spleen cells from nude mice also react with periodate, and their ability to respond to B cell mitogens is impaired after treatment with the chemical reagent.     

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.     

Behavior of aldehyde moieties involved in the activation of suppressor cells by sodium periodate

The treatment of mouse spleen cells with periodate at the optimal mitogenic concentration (1 mM) induces the activation of suppressor cells of the in vitro antibody response and leads to the formation of aldehydes on the carbohydrate termini of the surface sialoglycoconjugates. These aldehyde moieties are found on the C8 (N-AN 8) and the C7 (N-AN 7) derivatives of sialic acid. Immediate borohydride reduction prevents the activation of the suppressor cells. Data from this work show that borohydride reduction must be performed within the first 6 hr to prevent the generation of suppressor cells; 18 hr after the initial periodate oxidation, borohydride treatment did not reverse the in vitro suppressive activity of periodate-treated cells. The kinetics of the disappearance of aldehydes from the cell surface were studied by using [3H]borohydride labeling and chromatographic analysis of sialic acid derivatives. About 70 to 80% of the aldehyde moieties were found to be present 6 hr after periodate oxidation. After 18 hr, 50 to 70% of the aldehyde had disappeared from the lymphocyte membrane. Oxidized sialyl residues disappear completely after 60 hr of culture. This period corresponds to the de novo synthesis of sialic acid residues on the surface of periodate-activated cells. The two classes of oxidized sialyl-glycoconjugates were found to behave in different ways. In effect, our data showed that the aldehydes remaining at 18 hr are mainly located on the gangliosides, whereas the aldehyde moieties located on high m.w. glycoproteins disappear from the cell surface between 9 and 18 hr. This would suggest that the remaining aldehydes located on gangliosides are not directly involved in the expression of suppressive activity.     

Short-term stimulation of lymphocyte proliferation by indomethacin in vitro and in vivo

The effect of short-term (up to 24 h) in vitro and in vivo treatment with indomethacin was studied on the blastogenesis of mouse spleen cells. Indomethacin in itself induced a strong proliferation of the lymphocytes starting after 6 h treatment both in vitro and in vivo. Besides, significantly enhanced the blastogenesis of splenocytes in response to various doses of PHA and Con A. The stimulation of lectin-induced lymphocyte proliferation occurred after indomethacin treatment both in vitro and in vivo. Indomethacin had no major effect on the distribution of Lyt-1+ and Lyt-2+ subsets within the spleen cell population. An important role of the prostaglandins in the early phase of lymphocyte activation is suggested.     

A chemical approach for the localization of membrane sites involved in lymphocyte activation.

The aldehyde groups formed on periodate oxidation of cell surface sialyl residues were used to insert a mitogenic site onto the lymphocyte membrane by attachment of biotin hydrazide or 2,4-dinitrophenyl hydrazine. The biotin- or 2,4-dinitrophenyl-conjugated cells were both agglutinated and stimulated when cultured with avidin or anti-2,4-dinitrophenyl antibody respectively. On the other hand, biotin or DNP-conjugated cells, modified via functional groups on the membrane proteins, were agglutinated but not stimulated when cultured with avidin or anti-DNP antibody respectively. Our results show that the specific interaction of a protein at the periodate oxidation site leads to blastogenesis.     

Production of thymocyte-stimulating factor by murine spleen lymphocytes: cellular and biochemical mechanisms.

Cultures of murine spleen lymphocytes treated with Thy 1.2 antiserum plus complement do not produce thymocyte-stimulating factor (TSF). The population of thymocytes composed of immunocompetent, low-density cells produces only small amounts of TSF. Experiments with cyclophosphamide-injected mice and with spleen cells treated in vitro with antiserum to the murine B lymphocyte antigen plus complement and experiments using spleen cells stimulated in vitro with Sepharose-bound phytohemagglutinin indicate that B lymphocytes neither cooperate with T lymphocytes for the production of TSF nor produce TSF. Some lectins (pokeweed mitogen, Lens culinaris hemagglutinins A and B) have been found to induce the production of TSF by spleen cells. Other lectins (wheat germ agglutinin, Agaricus bisporus agglutinin) and sodium periodate do not. Spleen cells of mice immunized in vivo with keyhole limpet hemocyanin bound to bentonite particles or with BCG produce TSF when challenged in vitro with the specific antigen. Experiments using inhibitors of the macromolecular metabolism showed that DNA synthesis is not required for the production of TSF by spleen lymphocytes, whereas RNA and protein synthesis are required. Resolution of spleen lymphocytes on a discontinuous albumin gradient into six subpopulations showed that the TSF activity was rather uniformly distributed among the various subpopulations of cells.     

Effects of sodium periodate modification of lymphocytes on the sensitization and lytic phases of T cell-mediated lympholysis.

Sensitization of mouse splenic lymphocytes in vitro with sodium borohydride, suggesting that the biologic effects of sodium periodate are-treated autologous spleen cells stimulated a one-way mixed lymphocyte reaction and led to the generation of thymus-derived cytotoxic effector cells. These effectors were capable of lysing in 4 hr periodate-treated syngeneic and, to a lesser extent, periodate-treated allogeneic target cells. These results suggest that sensitization by periodate-treated autologous cells could result either from a specific reaction to modified self components or from a nonspecific mitogenic stimulation. Effector cells generated by allogeneic sensitization were detected on periodate-modified targets, irrespective of the H-2 antigens expressed by the targets. The effects of periodate modification on both stimulator and target cells were reversible by sodium periodate are dependent on the formation of a free aldehyde group on cell surface glycoproteins. Pretreatment of stimulator cells with neuroaminidase prevented the effect of periodate treatment, suggesting that the sensitization involves oxidized sialic acid residues. During the 4-hour 51Cr-release assay periodate-treated targets could be used to detect cytotoxic effector cells of any specificity. Fresh spleen cells and lymphocytes cultured for 5 days without antigen or in the presence of lipopolysaccharide did not lyse periodate-treated targets. An increasing level of cytotoxicity was detected on periodate-treated targets when the effector cells were generated, respectively, by stimulation with concanavalin A, by sensitization with periodate-modified autologous cells. Although the lysis of periodate-treated targets is itself nonspecific, effector cell specificity could be determined by selective blocking of the lytic phase with cells syngeneic to the stimulators. These results indicate that a nonspecific interaction can occur between lymphocytes and periodate-treated target cells, but that this interaction leads to lysis only when the lymphocytes were activated to become cytotoxic effectors.     

Control of proliferation in mitogen responsive human peripheral blood lymphocytes: restimulation of cells stimulated by sodium periodate.

Human peripheral blood lymphocytes are stimulated to a greater extent by sodium periodate when cells are incubated in medium containing human serum than when incubated in medium with fetal calf serum. NaIO4 STIMULATION CAN BE REVERSED BY TREATMENT WITH SODIUM BOROHYDRIDE BUT CELLS ALREADY COMMITTED TO DIVISION ARE NOT AFFECTED BY BOROHYDRATE TREATMENT. Maximal commitment to DNA synthesis of a NaIO4 oxidized cell suspens-on occurs after about 28 hr of incubation in medium. The committal time after periodate stimulation is identical to that after stimulation with concanavalin A. Cells treated with periodate and then reduced with borohydride immediately after oxidation are refractory to further per-odate stimulation. Cells stimulated with periodate and then incubated for 6 hr before treatment with borohydride can be restimulated with periodate, indicating a turnover of membrane sites in the 6 hr period. Periodate-stimulated cells divide only once in response to the stimulation. The progeny of cells which were stimulated with periodate can be restimulated by treatment with either periodate or concanavalin A.     

Plasmodium berghei: modification of sialic acid on red cells from infected mouse blood

The surface membrane glycoproteins of normal mouse erythrocytes can be labeled by oxidation with either periodate or galactose oxidase in the presence of neuraminidase, followed by reduction with NaB³H₄. Without neuraminidase there is little galactose oxidase-catalyzed labeling of protein. Analysis of labeled proteins by SDS-polyacrylamide gel electrophoresis showed that both methods labeled the same set of glycoproteins. Plasmodium berghei infection dramatically reduced the sialoglycoprotein labeling of red blood cells from infected blood using the periodate/NaB³H₄ method. Provided neuraminidase was present, labeling by the galactose oxidase method gave identical results to normal erythrocytes. We conclude that the glycoprotein sialic acid of uninfected as well as infected red cells is modified during infection such that it is refractory to periodate oxidation. Acylation of the exocyclic hydroxyls of sialic acid is suggested to account for this. Lectin binding and cell agglutination experiments using Limulin, soybean and wheatgerm lectins, and concanavalin A confirmed and extended these observations. The possible implications of these results with regard to anemia induced by malaria are briefly discussed.     

Characterization of mono-, di-, and tri-O-acetylated sialic acids on human cells

The presence of mono-, di-, and tri-O-acetylated sialic acids on human cells was demonstrated by using radiochromatographic and chemical techniques. Human melanoma cells and fresh colon tissue were biosynthetically labeled with 6- (3H) glucosamine. Radiolabeled sialic acids were hydrolytically removed from cellular glycoconjugates, purified by ion-exchange chromatography, and separated by paper chromatography on the basis of the number of O-substitutions on each sialic molecule. This analytical technique characterized radiolabeled sialic acids that migrated with the same Rf as synthetic mono-, di-, and tri-O-acetylated 14C-labeled sialic acids. The mono-O-acetylated sialic acids were characterized by their sensitivity to sodium periodate oxidation and a crude mouse liver esterase preparation. The di- and tri-O-acetylated sialic acids were characterized by their resistance to sodium periodate oxidation and sensitivity to the action of crude mouse liver esterase. Chromatographically separated di- and tri-O-acetylated sialic acids from normal human colon tissue were characterized by their respective ion molecular weights by using fast-atom bombardment-mass spectrometry. Using these methods, we chemically characterized mono, di-, and tri-O-acetylated sialic acids expressed on human cells. Aberrant expression of O-acetylated sialic acids was associated with adenocarcinoma of the colon, leading to a nearly complete loss of di- and tri-O-acetylated sialic acids.     

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.     

Sodium periodate stimulation of normal and chronic lymphocytic leukemia lymphocytes : II. The use of neuraminidase and trypsin to probe the nature of the response

Sodium periodate stimulated normal and leukemic lymphocytes to undergo DNA synthesis and cell division. The role exerted by cell surface components in this response was investigated by pre-treatment or post-treatment of cells with either neuraminidase or trypsin. Both enzymes substantially reduced the sodium periodate response of normal and leukemic lymphocytes when they were added after the mitogen. In normal lymphocytes when the treatment sequence was reversed (enzyme before sodium periodate), neuraminidase had no effect while trypsin greatly potentiated the action of this mitogen. In leukemic lymphocytes, however, neuraminidase reduced the response, whereas trypsin had little or no effect. In comparison with another mitogen, the response of normal and leukemic lymphocytes to phytohemagglutinin was not significantly altered by pre-treatment with neuraminidase or trypsin. Collectively, these results imply that significant differences exist in the cell surface of these two types of lymphocytes and that the oxidation of cell surface components other than sialic acid are involved in the response of these cells to sodium periodate.     

The role of membrane gangliosides in murine alveolar macrophage-mediated suppression of the immune response

Generation of aldehydes on cell membranes of viable alveolar macrophages (AM) by mild oxidation with sodium periodate was previously shown to result in total abrogation of AM-mediated suppression of the plaque-forming cell (PFC) response of spleen cells previously primed with sheep erythrocytes (SRBC). These results suggested a possible role for macrophage sialoglycoconjugates, such as gangliosides and sialoglycoproteins, in suppression. In the present report, it is shown that a purified mixture of gangliosides suppressed the PFC response of SRBC-primed spleen cells in a dose-dependent manner. Addition of rabbit anti-mouse brain antiserum (RAMB), which reacts with the gangliosides, reversed both ganglioside- and AM-mediated suppression of the PFC response. Pretreatment of AM but not spleen cells with RAMB also resulted in the reversal of AM-mediated suppression. The expression of gangliosides on the membrane of AM was detected with RAMB in an enzyme-linked immunosorbent assay (ELISA). The results suggest that membrane gangliosides may play an important role in the AM-mediated suppression of the PFC response. Since paraformaldehyde-fixed AM were not suppressive, it is speculated that AM release the suppressive gangliosides into the culture medium and rabbit anti-mouse brain antibody either prevents their release and/or neutralizes the suppressive function of released gangliosides.