Interaction of gangliosides with B cells in splenic fragment cultures

The effect of gangliosides upon murine adult B cells at the single precursor cell level was examined using the splenic focus assay. Adult B cells were stimulated in in vitro organ fragment culture by a hapten-modified carrier protein in the presence of an excess of carrier-primed T cells. The addition of a potential tolerogen in the form of antigen coupled to a carrier not previously presented to the T cells resulted in a temporary unresponsiveness of the onset of antibody production in adult B cells, but not a permanent state of tolerance. This delay could be eliminated by the addition of purified murine gangliosides during the presentation of the hapten coupled to the unrecognized carrier. The ganglioside preparation was fractionated by ion-exchange chromatography and the active fraction was found to be a disialoganglioside. These results suggest that the ganglioside may interfere with membrane receptor-related events occurring during or after antigen binding or cross-linking to responding B cells.     

Studies on the resistance to tolerance induction against human IgG in DDD mice. I. Organ differences of tolerogen susceptibility and cellular sites responsible for the resistance.

Cellular sites of the tolerogen resistance in DDD mice against human IgG (HGG) were examined by reconstitution experiments in which cells of various lymphoid organs from tolerized mice were transferred into lethally irradiated syngeneic recipients with or without the supplement of an excess number of untreated T or B cells. It was shown that T cells but not B cells in the spleen and bone marrow-locating B cells were tolerogen resistant. Kinetic profiles of tolerance induction were compared among thymus, lymph node, and spleen T cells. Thymus cells fall into unresponsive state as early as 2 days after the tolerogen (tHGG) injection when only partial tolerance was observed in lymph node T cells. By 1 week of tolerogen treatment, the tolerant state was completed in both thymus cells and lymph node T cells, while spleen T cells showed marked resistance. Tolerance induced in thymus cells and spleen T cells was of relatively short duration and responsiveness was completely recovered by 5 weeks after the injection of tHGG. At this time lymph node T cells still showed hyporesponsiveness. The differences in tolerance inducibility were also shown among different lymphoid organs in tolerogen dose response. Lymph node T cells were very sensitive to tolerance induction, giving no response even by the injection of 0.01 mg of tHGG. Thymus cells were much less sensitive with the gradual loss of responsiveness by increasing the amount of tHGG. In contrast, spleen T cells showed gradual resistance with increasing amount of tHGG, indicating that some positive response was evoked in spleen T cells by a relatively high dose of tHGG. These results seem to suggest that the tolerogen resistance of spleen T cells may be due to their capability of showing positive response against the tolerogenic material. This was also suggested by the fact that the treatment with cyclophosphamide following the tolerogen injection diminished completely the responsiveness against the subsequent challenge immunization.     

Interference with tolerance induction of primed B cells by the Fc fragment of immunoglobulin

The capacity to interfere with tolerance induction in primed B cells was examined. Previous work had shown that TNP-specific splenic B cells from mice primed and boosted with TNP-KLH are highly susceptible to in vitro tolerization upon a brief exposure to TNP on a carrier unrelated to KLH. In the present work it was found that tolerance induction in these primed B cells could be partially disrupted by addition of the Fc fragment of immunoglobulin, a B-cell mitogen, and adjuvant, during exposure of the B cells to tolerogen. Addition of Fc fragments prepared by papain digestion of human IgG interfered with tolerization routinely in approximately 30-60% of the spleen cells susceptible to tolerogen. Addition of whole IgG or Fab fragments had no effect on tolerance induction. As little as 5 micrograms/ml of the Fc fragment preparation significantly interfered with tolerization and 32-64 micrograms/ml was optimal. Disruption of tolerization was most effective when the Fc fragment was added to the spleen cells either 4 hr prior to tolerogen or simultaneously with tolerogen; addition of the Fc fragment 4 hr after exposure to tolerogen was significantly less effective. Disruption of tolerization by the Fc fragment was not through polyclonal activation of B cells, as antigen was required for generation of significant numbers of PFC to TNP. Also, disruption was not through expansion of low avidity clones of B cells insusceptible to tolerogen, as the avidity of the antibody produced with and without Fc fragments present was approximately the same. These results show that the Fc fragment of IgG can partially interfere with tolerization of primed B cells. The manner in which Fc fragments may function to prevent tolerization through its lymphoid cell stimulatory capacities is discussed.     

Membrane defects of the tolerant B cell. I. Failure of antigen-induced capping.

In order to study the membrane function of tolerant B antigen-binding cells, tolerance to the trinitrophenyl (TNP) determinant was induced in mice by injecting the reactive form of the hapten, trinitrobenzene sulfonic acid (TNBS). By appropriate transfer experiments, Fidler and Golub (J. Immunol.112, 1891, 1974) had previously shown that this form of tolerance is a B-cell property, induced and expressed in the absence of T cells. Hapten inhibition demonstrated the TNP-specificity of receptors on TNP-donkey erythrocyte(TNP-D)-binding cells in tolerant and nontolerant mice. About 88% of these cells were B cells by immunofluorescence, and the remainder were T cells. In the tolerant mice, challenge with TNP-sheep erythrocytes failed to expand the TNP-binding population, but sheep erythrocyte binders and anti-sheep plaque-forming cells expanded normally. Despite little or no change in TNP-binding cell numbers after tolerance induction, the TNP-binding cells of tolerant animals could not cap their receptors, in contrast to the sheep erythrocyte-binding cells from the same animals which capped normally. Although there is no anti-TNP plaque-forming cell response when tolerogen and immunogen are given simultaneously, capping failure is not evident until 2–4 days after tolerogen exposure. By Day 7, substantial recovery of immune responsiveness had occurred, yet even 12 months after a single dose of tolerogen there was no restoration of capping. Thus despite the association of both capping failure and unresponsiveness with tolerogen exposure, these lymphocyte functional defects appeared not to be causally related.     

Influence of cortisone on immunologic tolerance in vivo: Cortisone prolongs the duration of unresponsiveness but fails to affect its induction

The influence of cortisone administration on either the induction or the duration of immunologic tolerance was examined in vivo. Tolerance induced by isologous IgG coupled to fluorescein was chosen because the hapten-bearing cell can be directly visualized and the hapten-specific immune response to either a TD antigen or a TI₂ antigen can be tested. It was found that cortisone facilitates the maintenance of tolerance, but fails to affect its induction to either class of antigen. Fluorescein-IgG-bearing cells are cortisone resistant. They are seen for a longer period of time in animals treated with cortisone and tolerogen than in animals treated with tolerogen, and fluorescent cells are either T or B cells. We propose that cortisone facilitates the maintenance of tolerance by maintaining a receptor blockade in vivo. This finding might have clinical implications for the treatment of autoimmunity.     

T cell tolerization in vitro: modulation of helper and suppressor cell activities

This paper analyzes the conditions for in vitro tolerization of purified whole T cell populations and the consequences on helper and suppressor T cell functions. Highly purified splenic T cells from adult DBA/2 mice were incubated in vitro for 24 hr with high doses of trinitrophenyl coupled to human gamma-globulins (TNP-HGG). A profound inhibition of the TNP-specific helper function of these T lymphocytes was observed in a cooperative culture with normal purified splenic B cells and TNP-SRBC as antigen. This state of specific unresponsiveness was maintained after trypsin treatment of the cells, at the end of the 24-hr incubation with the tolerogen. We checked that this procedure removed the vast majority of F23.1 T cell receptor determinants from the cells. This result indicates that T cell receptors for antigen were not merely blocked by the tolerogen. In addition, B cells preincubated with tolerized T cells for 24 hr remained as responsive to TNP as B cells mixed with normal T cells in similar conditions. This demonstrates that the decreased response is not the result of secondary B cell tolerization. In addition, anti-Ia monoclonal antibodies were shown to block the induction of tolerance. We also showed that tolerized T cells significantly decreased the anti-TNP response of normal T and B cells in vitro, whereas the anti-SRBC response in the same cultures was unaffected. When tolerized T cells were separated into Lyt-2- and Lyt-2+ cells, it was found that tolerized Lyt-2- cells had lost about 75% of their helper activity and that Lyt-2+ cells suppressed 70% of the response of a normal T and B cell culture. Thus, in vitro induction of T cell tolerance results in a specific T cell unresponsiveness which is due to both helper T cell inactivation and induction of specific suppressor T cells.     

A novel role for macrophages: the ability of macrophages to tolerize B cells

We investigated the ability of macrophages (M phi) to present the tolerogen fluoresceinated sheep gamma-globulin (FL-SGG) to B cells. M phi pulsed with FL-SGG or murine FL-IgG2 were able to tolerize normal spleen B cells specifically as assessed by the plaque-forming cell (PFC) response to the antigens FL-Brucella abortus (FL-BrA) and FL-polymerized flagellin (FL-POL). Tolerance was not induced when M phi were pulsed with a variety of other FL antigens or the synthetic tolerogen FL-D-glutamic acid-D-lysine (FL-D[G,L]). The ability of M phi to tolerize B cells was not T cell-dependent, because populations of both T-depleted B cells and hapten-specific B cells were tolerizable. M phi-induced B cell tolerance did not exhibit genetic restriction with regard to the H-2 haplotype of the presenting M phi or the responding B cells. A variety of different types of peritoneal M phi, including normal resident M phi and those elicited by thioglycollate or concanavalin A (the latter are predominantly la+), could tolerize B cells after being pulsed with FL-SGG. We compared tolerogen-pulsed M phi to soluble tolerogen for the ability to tolerize B cells and found that tolerogen bound to M phi was more than 10 times as potent as an equivalent amount of soluble tolerogen. In contrast to the ability of M phi to present FL-SGG in a tolerogenic fashion to B cells, the P388AD lymphoid dendritic cell-like tumor line presented FL-SGG in an immunogenic mode to B cells. Tolerogen bound to P388AD cells could specifically augment a PFC response to both FL-BrA and FL-POL. We suggest that certain types of M phi may play a role in unresponsiveness by enhancing the tolerogenicity of soluble antigen, whereas other accessory cells may present the same moieties in an immunogenic fashion.     

Hapten-specific murine colony-forming B cells. II. Delineation of a tolerogen-sensitive subpopulation of colony-forming B cells

B cell subpopulations were studied by using B cell cloning procedures and an in vitro tolerance induction model. Fluorescein- (FL) specific B cells from normal spleens were isolated by using FL gelatin plates and were then cultured in semisolid agar in the presence or absence of tolerogen. Hapten-specific cells grew in soft agar to form discrete colonies. Colony growth is dependent on "mitogens" present in agar, sheep red blood cells (SRBC), and lipopolysaccharide (LPS). For example, SRBC plus LPS potentiate the growth of an increased number of colony-forming B cells (CFU-B) compared to either additive alone. These CFU-B could be triggered by a specific antigen to yield plaque-forming cells (PFC). With tolerogen (FL-sheep gamma-globulin) present in the agar, the number of FL-specific CFU-B was reduced by 25 to 50%. The ability of the remaining colonies to form PFC upon antigenic stimulation was also reduced. This reduction in CFU-B numbers, however, was observed only when the agar contained both SRBC and LPS as mitogenic potentiators of growth; no effect of tolerogen on CFU-B numbers was seen when cells were grown with either additive alone. Interestingly, the effect of tolerogen on CFU-B numbers was abrogated when peritoneal macrophages, in addition to SRBC plus LPS, were present during cloning. It is postulated that unique subpopulations of B cells form colonies under varied cloning conditions and that those CFU-B grown with SRBC plus LPS display an increased sensitivity to growth inhibition by tolerogen.     

Establishment of unresponsiveness in primed B lymphocytes in vivo

As an approach to examine the influence of the state of cellular activation on the ability to tolerize B cells, the induction of unresponsiveness in human gamma-globulin-(HGG) primed B lymphocytes was studied in an adoptive transfer system. In contrast to transferred normal spleen cells, spleen cells from HGG-primed mice are not readily rendered unresponsive when exposed to the tolerogen, deaggregated HGG (DHGG), in irradiated recipients. A kinetic study showed that unfractionated primed spleen cells do not respond to an antigenic challenge given between 6 and 10 days after cell transfer and injection of DHGG, indicating that they are transiently depressed. In contrast, isolated primed B cells are tolerized when transferred to recipients and treated with DHGG in the absence of T cells. Furthermore, primed B cells exposed to tolerogen in the recipients do not recover the ability to respond to HGG either after a secondary challenge with AHGG given up to 14 days after transfer, or after 2 consecutive challenges given on days 14 and 24 after transfer. The presence of primed T cells at the time of tolerization interferes with the induction of unresponsiveness in these primed B cells. These studies suggest that the presence of primed T cells is responsible for the inability to tolerize unfractionated primed spleen cells populations and that primed B cells themselves are not intrinsically resistant to the induction of unresponsiveness.     

Tolerance susceptibility of newly generating memory B cells

Newly generating memory B cells rapidly accumulate somatic mutations that can alter their Ag-combining sites and potentially engender recognition of self determinants. To investigate the possibility that, during their emergence secondary B cells pass through a window of tolerance susceptibility, we have examined the in vitro generation of memory B cells in the presence or absence of tolerogen. The findings indicate that, before antigenic stimulation, precursors to memory B cells are resistant to tolerance induction. However, 2 to 7 days after T cell-dependent antigenic stimulation, newly emerging hapten-specific secondary B cells can be inactivated by the presence of hapten on a carrier not recognized by available Th cells. This inactivation can be blocked by the presence of free hapten and can be competed by the presence of immunogen. Inactivation of newly generating secondary B cells appears less specific than the tolerance induction of immature neonatal or bone marrow B cells because inactivation can be accomplished by cross-reactive determinants. Interestingly, the presence of tolerogen after primary stimulation did not preclude the generation of cells responsive to a third in vitro stimulation. Therefore, whereas newly emerging memory B cells are highly susceptible to inactivation, the progression of the clones of progenitors to memory B cells appears resistant to tolerance induction.     

Membrane defects in the tolerant B cell. II. Mechanism of capping failure and reversal by antigen exposure.

The demonstration that TNP-binding B lymphocytes from animals whose B cells have been rendered tolerant to TNP by trinitrobenzene sulfonic acid cannot undergo antigen-induced capping of their TNP receptors for at least a year despite recovery of immune responsiveness has led to a search for the mechanism of the capping failure. Microtubule-dependent membrane “locking” analogous to that induced by concanavalin A appears to afflict the tolerant B cells, in that capping TNP receptors is restored after exposure to 10^?4M colchicine or overnight incubation at 4 °C. Assignment of the defect to the cytoskeleton rather than the receptors themselves is also supported by the observations that enzymatic stripping and regrowth of receptors does not unlock the cell and that non-Ig membrane molecules recognized by antilymphocyte serum also cannot be capped on the tolerant cells. Cells which have remained locked for 4 days to 8 months after a single tolerogen exposure become unlocked 4 days after immunogen is given. Four days after immunogen, tolerogen fails to lock the membranes of TNP-binding cells. These results suggest that tolerogen contact interferes in a much broader range of functions in the TNP-binding cell than those which affect the immune response. Among these effects is a remarkably stable “locked” configuration of the cytoskeleton which is independent of immune responsiveness or receptor turnover, but which can be reversed by exposure to immunogen whether or not an immune response ensues.     

Defective B cell tolerance induction in New Zealand black mice. I. Macrophage independence and comparison with other autoimmune strains

B cell unresponsiveness was examined in vitro by using spleen cells from autoimmune NZB, BXSB/Mp male, MRL/Mp-Ipr/Ipr (MRL/l), and control mice, and the tolerogen trinitrophenyl human gamma-globulin (TNP-HGG). The B cell subset responsive to TNP-Brucella abortus in each autoimmune and control strain that was tested was highly susceptible to tolerance induction with the use of high epitope density conjugates (TNP30HGG and TNP32HGG). When a tolerogen with a lower epitope density was used (TNP7HGG), several control strains were all rendered tolerant in a thymic-independent and hapten-specific manner. NZB B cells were resistant to all concentrations of TNP7HGG tested, whereas B cells from BXSB/Mp male and MRL/1 mice were resistant to low concentrations of this tolerogen. NZB mice were resistant in addition to tolerance induction with TNP9HGG, TNP10HGG, and TNP12.7HGG. Experiments were performed to determine whether splenic macrophages played a role in resistance to tolerance in NZB mice. The mixing of NZB and control DBA/2J T cell-depleted splenocytes revealed no modulatory effects by the accessory cells in culture. Moreover, B cells rigorously depleted of macrophages by double Sephadex G-10 column passage exhibited characteristic patterns of resistance or susceptibility in NZB and control strains, respectively. These findings support the conclusion that resistance to tolerance in NZB mice is determined at the B cell level and are consistent with the hypothesis that diverse immunoregulatory disturbances contribute in varying degrees to the development of systemic lupus erythematosus in different inbred strains of mice.     

Tolerance and immunity in antigen-specific B-lymphocyte lines: early receptor binding of either antigen or tolerogen initiates an immune response

Studies of the effect of tolerance-inducing compounds on B lymphocytes have been complicated by the fact that it is technically difficult to completely isolate the antigen-specific B cell from the effects of T cells or T-cell factors. We have used our cell lines of nonmalignant dinitrophenyl (DNP)-specific B lymphocytes derived from normal mice, which have no contaminating T cells, to study the effect of DNP-murine IgG2a (DNP-MGG), a tolerogen which is not normally immunogenic, on antigen-specific B lymphocytes. Preincubation with DNP-MGG for 48 hr, both in the presence and absence of T-cell factors from EL-4 supernatant prior to adding the antigen DNP-Ficoll, can induce tolerance in cell line B lymphocytes. The suppression is antigen-specific since preincubation with fluorescein-MGG or unconjugated MGG does not suppress the anti-DNP response. At least a 36-hr incubation is required for tolerance induction in B lymphocytes, but a 6-hr preincubation with DNP-MGG augments the immune response to DNP-Ficoll. Lymphocytes incubated for 6 or 24 hr with DNP-MGG prior to adding EL-4 supernatant and filler cells without DNP-Ficoll exhibited an immune response equal to that elicited by DNP-Ficoll and T-cell factors. A 6-hr pulse with a DNP-conjugated polymer of D-glutamic acid and D-lysine (DNP-dGL), a B-cell tolerogen which does not bind to Fc receptors, elicited the same immune response as seen with a 6-hr pulse of DNP-MGG but a 48-hr preincubation with DNP-dGL induced tolerance. Thus, it is likely that the initial binding of the tolerogen to the immunoglobulin receptor on the mature B cell elicits an activation signal similar to that seen with the antigen. The suppressive effect of the tolerogen itself appears to occur at a later stage of the process of the B-cell activation, proliferation, and differentiation.     

Ability of tolerized Th1 and Th2 clones to stimulate B cell activation and cell cycle progression.

Tolerant and nontolerant murine Th1 and Th2 clones, specific for human gamma-globulin (HGG), were compared for their ability to promote cell cycle entry and progression by B cells in vitro. When stimulated with HGG, nontolerant Th1 and Th2 clones induced similar increases in B cell membrane MHC class II levels--a phenomenon associated with early B cell activation. Nontolerant Th1 and Th2 clones also induced B cell DNA synthesis, an event associated with subsequent G1 phase traversal, although Th2 cells were more efficient than Th1 cells in stimulating this activity. Exposure of Th clones to tolerogen in the form of HGG-pulsed chemically fixed APC inhibited the ability of Th1 clones, but not Th2 clones to promote polyclonal B cell DNA synthesis in HGG-stimulated secondary cultures. However, Th1 clones exposed to tolerogen did not lose their ability to increase the expression of MHC class II molecules on B cells in these cultures. These results indicate that tolerance induction does not inhibit the ability of Th1 clones promote B cell cycle progression. In contrast, exposure of Th2 cells to tolerogen does not inhibit significantly the ability of these cells to stimulate B cell cycle entry or progression.     

Cellular events in tolerance IX: Maintenance of immunological tolerance in the presence of normal B-cell precursors and in the absence of demonstrable suppression

The cellular events involved in immunological tolerance to fluoresceinated sheep gammaglobulin (FL-SGG) were analyzed at the level of hapten-specific B cells. One single iv injection of FL-SGG induced tolerance as measured by challenge with thymus-dependent (FL-KLH) or thymus-independent (FL-Ficoll) antigens in vivo or thymus-independent (FL-LPS) antigen in vitro. As noted earlier, unresponsiveness was maintained until 6–8 weeks after tolerance induction. Limiting-dilution precursor analysis demonstrated a reduction in B-cell precursors on Day 7 after tolerogen treatment; precursor frequencies returned to control levels by 3–4 weeks. This recovery of precursors in the presence of stable tolerance was not due to suppressor activity. Rather, results show that tolerant hapten-specific B cells are clonally anergic and display a reduced burst size in response to antigen. Hence, unresponsiveness is maintained in the presence of apparently normal precursor levels by an intrinsic defect in antigen-specific B cells.     

Differential regulation of peripheral CD4+ T cell tolerance induced by deletion and TCR revision

In Vbeta5 transgenic mice, mature Vbeta5(+)CD4(+) T cells are tolerized upon recognition of a self Ag, encoded by a defective endogenous retrovirus, whose expression is confined to the lymphoid periphery. Cells are driven by the tolerogen to enter one of two tolerance pathways, deletion or TCR revision. CD4(+) T cells entering the former pathway are rendered anergic and then eliminated. In contrast, TCR revision drives gene rearrangement at the endogenous TCR beta locus and results in the appearance of Vbeta5(-), endogenous Vbeta(+), CD4(+) T cells that are both self-tolerant and functional. An analysis of the molecules that influence each of these pathways was conducted to understand better the nature of the interactions that control tolerance induction in the lymphoid periphery. These studies reveal that deletion is efficient in reconstituted radiation chimeras and is B cell, CD28, inducible costimulatory molecule, Fas, CD4, and CD8 independent. In contrast, TCR revision is radiosensitive, B cell, CD28, and inducible costimulatory molecule dependent, Fas and CD4 influenced, and CD8 independent. Our data demonstrate the differential regulation of these two divergent tolerance pathways, despite the fact that they are both driven by the same tolerogen and restricted to mature CD4(+) T cells.     

Gangliosides enhance migration of mouse B16-melanoma cells through artificial basement membrane alone or in presence of laminin or fibronectin

The migration of B16LuF1 cells, B16-melanoma cells of lower metastatic potential to lung was enhanced through artificial basement membrane in presence of gangliosides of B16LuF1 cells as well as gangliosides of B16-melanoma cells of higher metastatic potential to lung, namely, B16LuF5 and B16LuF10 cells. The same concentration (50 microM) of gangliosides of B16LuF1, B16LuF5 and B16LuF10 cells gradually increased the migration of B16LuF1 cells through basement membrane. Moreover, B16LuF10 cell gangliosides modified the migratory effect of laminin and fibronectin on B16LuF1 cells. Laminin alone increased migration of B16LuF1 cells whereas fibronectin alone decreased migration of the same cells. When B16LuF10 cell gangliosides were used in combination with fibronectin, gangliosides removed the migration inhibitory effect of fibronectin resulting in net enhancing effect. Gangliosides in association with laminin also increased the enhancing effect of laminin on migration of B16LuF1 cells. Thus, gangliosides showed additive enhancing effect when used in combination with laminin. However, effect of individual gangliosides were different. Out of six gangliosides isolated from B16LuF10 cells only two gangliosides corresponding to standard gangliosides GM2 and GM3 enhanced migration of B16LuF1 cells. The migration of B16LuF1 cells in presence of each of the remaining four gangliosides corresponding to GT1b, GD1b, GD1a and GM1 was not altered and was comparable to that of untreated control. Thus, gangliosides of B16 melanoma cells alone or in combination with laminin or fibronectin enhanced migration of B16 melanoma cells through artificial basement membrane, suggesting possible role of tumor gangliosides during invasion of metastatic tumor cells through basement membrane of the surrounding tissues in vivo.     

Structural characterization of gangliosides from murine T lymphocytes

Mouse spleen cells were prepared from CBA/J mice, and T lymphocytes were selectively stimulated with the T cell mitogen concanavalin A and further propagated in the presence of the T cell growth factor interleukin-2. The T cells were metabolically labeled with D-[1-14C]galactose and D[1-14C]glucosamine, and the gangliosides were extracted and purified by DEAE-Sepharose column chromatography. Carbohydrate backbone structures of the asialogangliosides, prepared by mild acid hydrolysis, were determined by high-performance liquid chromatography, treatment with exoglycosidases and immunostaining. Monosialylated gangliosides were isolated by gradient elution from DEAE-Sepharose and further separated by preparative high-performance thin-layer chromatography in two solvent systems. Isolated fractions were characterized by preparation of asialogangliosides by mild acid hydrolysis, the action of Vibrio cholerae neuraminidase, and fast-atombombardment mass spectrometry. The following structures were identified: IVNeuAc-GgOse4Cer; IVNeuGc-GgOse4Cer; IVNeuAc-GgOse5Cer; and IVNeu-Gc-GgOse5Cer. The latter two gangliosides were not detected on B lymphoblasts and may be T-cell-specific structures. All gangliosides were heterogeneous in their ceramide moieties, being substituted with C16:0, C24:0, and C24:1 fatty acids. A preliminary study of several other mouse strains showed no strain-specific genetic variations in the T cell gangliosides. The possible role of these gangliosides is discussed.     

Interference with tolerance induction in vivo by inhibitors of prostaglandin synthesis

Prostaglandins (PG) have been implicated as modulators of both humoral and cellular immune responses. In order to evaluate a possible role for PG in tolerance, the effect of inhibitors of prostaglandin synthesis on tolerance induction and circumvention has been investigated. Injection of deaggregated human gamma-globulin (DHGG) into A/J mice leads to unresponsiveness to a subsequent challenge with immunogenic aggregated human gamma-globulin (AHGG). Administration of indomethacin (IM) or acetylsalicylic acid (ASA) shortly before and after DHGG injection prevents tolerance induction. PGE2 reverses the tolerance overriding effect provided by IM. IM is not able to overcome unresponsiveness when given 10 and 20 days after tolerance induction, at a time point when both T and B lymphocytes are tolerant. As previously shown, lipopolysaccharide (LPS) both inhibits the induction of tolerance to HGG and circumvents tolerant T helper cells late in tolerance when competent B cells are present. In contrast, IM is unable to circumvent T-helper cell tolerance when given at Day 60 after tolerogen, when B cells (but not T cells) are responsive. Furthermore, LPS acts as an adjuvant, B-cell mitogens, inducer of polyclonal Ig secretion, and primes mice when given with tolerogen, while IM has none of these properties. These results indicate a difference between the effects of IM and LPS on tolerance and a possible role of PG in DHGG-mediated tolerance induction.     

Gangliosides of murine T lymphocyte subpopulations

Gangliosides from murine T lymphoblasts were analyzed by high-performance thin-layer chromatography followed by in situ neuraminidase treatment and immunostaining of the resulting asialogangliosides and compared with those from thymocytes and cloned T lymphocytes with defined functions. The ganglioside IVNeuGc/Ac-GgOse5Cer (GalNAc-GM1b), a marker for T lymphoblasts [Müthing, J., Egge, H., Kniep, B., & Mühlradt, P. F. (1987) Eur. J. Biochem. 163, 407-416], was found only in small amounts as the N-acetylated species in gangliosides from thymocytes and a cytolytic T cell clone. Two helper clones expressed this ganglioside like T blasts. The structures of the two major disialogangliosides from T blasts, IVNeuAc,IIINeuAc-GgOse4Cer (GD1 alpha type) with C24:0/24:1 and C16:0 fatty acids, were elucidated by neuraminidase treatment and immunostaining and by fast atom bombardment mass spectrometry. Gangliosides of this type were detected in thymocytes only in minor amounts, whereas GM1b-type gangliosides prevailed in cells from this organ. Analysis of the T lymphoblast gangliosides from six genetically unrelated mouse strains showed that terminally sialylated GgOse4Cer (GM1b), IVNeuAc-GgOse5Cer (GalNAc-GM1b), and IVNeuAc,IIINeuAc-GgOse4Cer (GD1 alpha) were conserved structures in all strains examined. We conclude that maturation or stimulation of T cells may be correlated with elongation of a common GM1b-type precursor structure resulting in GalNAc-GM1b or GD1 alpha-type gangliosides.