Immune response to bacterial dextrans. II. T cell control of antibody isotypes

Understanding thymus-independent antigen-induced reduction of thymus-dependent immune responses

Deficiencies in immune responses against polysaccharides can have direct consequences for patients, and therefore, a better understanding of these immune reactions is crucial. We have studied the immune response against the polysaccharide dextran B512 (Dx). Administration of immunogenic doses of thymus-independent (TI) Dx reduces the immunoglobulin G1 response to later challenges with a thymus-dependent (TD) form of Dx. We investigated if this suppression is a general phenomenon caused not only by Dx but also by other TI antigens, and examined possible mechanisms contributing to this unresponsiveness. We show that clonal exhaustion is not involved in modulating subsequent responses, nor is signalling via FcgammaRIIB or other antibody mediated pathways. The reduced TD response is not an exclusive Dx phenomenon; it is also induced by TI antigen oxazolone (Ox). However, responses against the hapten dinitrophenyl (DNP) are not affected, indicating that the TI priming negative effect is not a general process. This may be explained by the restricted immune response to both Dx and Ox, in contrast to the unrestricted DNP response. Our conclusion from these experiments is that the underlying mechanism for the TI-induced reduction of latter TD responses is a property of the TI activation itself.

T-Independent IgA Responses to Microbial Polysaccharides

There is accumulating evidence indicating the presence in vivo of T-independent routes of IgA response in addition to the conventional T-dependent IgA response. Factors influencing these alternative pathways of IgA responses may include the structural characteristics of a stimulating antigen, the nature of responding B cells, and the microenvironment. The structural complexity of polysaccharide antigens has made it difficult to summarize a general scheme for the antibody responses they induce. Instead, one may expect that each individual polysaccharide may be able to create a unique microenvironment by activation of specific cell populations in the repertoires of non-T cell types. A specific pattern of B cell response may thus be elicited by TI stimulation. Recognition of such a unique property of a TI antigens is necessary for us to better understand the T-independent IgA response. Information obtained may have an impact on the development of vaccination strategies directed at the mucosal immunity mediated by IgA antibodies.

Serum antibody and cellular immune response in mice to dextran B512

Serum antibodies to dextran started to appear 3 days after immunization of C57BL/6 mice. Synthesis of IgM antibodies was followed by IgG3 and IgGA. Other immunoglobulin classes (IgG1, IgG2b, and IgG2a) were very low or absent. The immune response to dextran was also thymus independent with regard to IgG3 and IgA synthesis as demonstrated by the use of nu/nu mice. CBA and C57BL/6 mice were high responders to dextran with regard to IgM synthesis. C57BL/6 mice produced high levels of IgG3 and IgA antibodies, whereas CBA, A/J, and A.TL only synthesized IgM antibodies. A/J and A.TL strains were most frequently low responders with regard to IgM synthesis and CBA/N mice were completely nonresponders with regard to all immunoglobulin classes. The ability to produce anti-dextran antibodies increased with age in high responder strains. This was most pronounced for IgG3 and IgA antibodies, which reached adult levels 3 months after birth. The affinity of anti-dextran antibodies was high and homogeneous in antisera from C57BL/6 mice. Preimmune matural antibodies and antibodies from immunized low responder strains had a low and variable affinity for dextran.

A comparison of the IgG isotype expression in the so-called thymus-independent immune responses to alpha(1----3) and alpha(1----6) dextran

This paper presents data on the IgG antibody response against two "thymus-independent" dextran (Dex) antigens from Leuconostoc mesenteroides, alpha(1----3) Dex B 1355S and alpha(1----6) Dex B 512F in BALB/c and C57BL/6 mice, which are considered to be responders or low responders to the respective antigen. The data point toward three common rules governing the two anti-Dex responses despite immunogenetic and antigenic disparities: (1) age dependency of the IgG isotype regulation of the response; (2) down-regulation of IgG isotype expression by T cells; and (3) individually determined preposition for IgG isotype formation in a given animal.

T-cell-dependent modulation of the polyclonal B-lymphocyte responses in normal spleen cell cultures stimulated by lipopolysaccharide

The in vitro polyclonal B-cell proliferative and plaque-forming cell (PFC) responses to the T-independent (TI) mitogen lipopolysaccharide (LPS) are increased by the addition of normal syngeneic splenic T cells. Normal irradiated Lyt-2- T cells also alter the IgG subclass distribution from the typical predominance of IgG3 and IgG2b PFC to the appearance of IgG1, IgG2a and IgA PFC in T-cell-depleted spleen cell (SC) cultures. Furthermore, secondary LPS blast cultures yield increased PFC responses when co-cultured which syngeneic fresh normal T cells which, even in the absence of mitogen, induce PFC responses in such activated B cells. As LPS blasts induce normal syngeneic T cells to proliferate and significant numbers of L3T4+ blast cells are found in LPS-stimulated normal spleen cell cultures, we conclude that T cells actively participate in the regulation of these responses. The significance of these findings for the regulation of TI responses in vivo by "autoreactive" T cells is considered.

The immune response to bacterial dextrans. III. Ontogenic development and strain distribution of specific clonal precursors

The frequencies of B512 dextran (Dex)-specific B cell precursors were determined by limiting dilution analysis in a number of mouse strains originally described as "high responder", "low responder" and "nonresponder" to this antigen. No significant difference in the frequencies of Dex-specific precursors was found in C57BL/6, B10.BR, C3H/Tif, BALB/c and A/Sn adult mice. Together with the large intra-strain variability in the magnitude of anti-Dex PFC responses in vivo, these results established that differential reactivity in vivo cannot be ascribed to genetically controlled absence or wide variation in the frequency of Dex-specific immunocompetent precursors. A similar analysis of the Dex-specific precursor frequency was carried out in C57BL/6 mice between 1 week and 3 months of age. While no Dex-specific antibody response was detected in vivo before the age of 3 weeks, clonal precursor analysis revealed that the appearance of these specificities parallels the development of competent (IgM-producing) B lymphocyte clonal precursors, such that no significant difference in absolute frequencies of Dex-specific precursors could be observed among these age groups. This is interpreted to suggest that the late development of the Dex-specific antibody responses is regulatory rather than due to late rearrangement and activation of the appropriate V genes and a sequential expression of antibody specificities in ontogenic development.

Differential effect of interferon-gamma and interleukin-2 on the induction of IgA and IgM anti-dextran responses

Supernatants from T-cell lines and T-cell hybridomas can substitute for T cells in the induction of the anti-alpha(1,3) Dextran B1355 plaque-forming cell response in culture. The present study sought to define the lymphokines required for the induction of IgA and IgM anti-alpha (1,3) dextran responses. Recombinant Interferon-gamma (IFN-gamma) supported the induction of low levels of IgA anti-alpha(1,3) dextran plaque-forming cells in splenic B-cell cultures. IgA responses were substantially increased when cultures containing IFN-gamma were supplemented with an interleukin 2 (IL-2)-containing supernatant from the murine T-cell hybridoma BW.Mls, purified murine IL-2, or recombinant human IL-2. In striking contrast, IgM anti-alpha(1,3) dextran plaque-forming cells were not produced in cultures containing IFN-gamma alone or in combination with purified or recombinant IL-2. However, substantial IgM responses could be produced in cultures containing IFN-gamma and BW.Mls supernatant. This data indicates that there may be different lymphokine requirements for the induction of IgA and IgM anti-alpha(1,3) dextran B cells, or alternatively, such B cells may be in different stages of differentiation and therefore, not respond to the same lymphokines.

Isotypes of antibodies induced by plain dextran or a dextran-protein conjugate

Mice were immunized with alpha (1----6) dextran or its protein conjugate with monthly intervals, and their antibodies were quantitated with an isotype-resolved radioimmunoassay. Plain dextran (molecular weight = 5-40 million) induced antibody concentrations varying from 20 to 80 micrograms/ml (primary response). The response to a booster injection was weaker than the response to the first injection. More than 90% of anti-dextran antibodies were IgM but IgG and IgA responses could be unequivocally demonstrated. IgG1 and IgG3 were the predominant subclasses of IgG. Dextran antibody responses to a conjugate of dextran (molecular weight approximately equal to 10000) and chicken serum albumin (CSA) were stronger (80-300 micrograms/ml) than responses to plain dextran, and anti-CSA responses to the conjugate were even stronger (up to 900 micrograms/ml). Three distinctly different isotype patterns were observed. A pattern IgM much greater than IgG1 = IgG3 greater than IgG2a prevailed in responses to the plain dextran and in primary anti-dextran responses to dextran-CSA. Another pattern IgG1 greater than IgG3 greater than IgM greater than IgG2a was observed in late anti-dextran responses to dextran-CSA. The third pattern IgG1 much greater than IgG2a greater than IgG3 approximately equal to IgM was characteristic of anti-CSA antibodies. Little IgG2b or IgA antibodies were found. Different isotype patterns can best be explained on the basis of secondary factors such as T cell help.

Immunoglobulin subclass distribution of human anti-carbohydrate antibodies: aberrant pattern in IgA-deficient donors

The IgG and IgA subclass distribution of anti-carbohydrate antibodies in normal and immunodeficient donors was investigated. In normal donors, the specific anti-dextran antibodies were mainly of the IgG2 and IgA2 subclass, although substantial amounts of antibodies could also be of the IgG1 subclass. In children, IgG1 was the predominant subclass expressed. An aberrant IgG subclass distribution pattern of specific antibodies occurred in some IgA-deficient donors, with preferential expression of IgG1 and IgG3 anti-dextran antibodies.

Immunogenic properties of octasaccharide-protein conjugates derived from Klebsiella serotype 11 capsular polysaccharide

The tetrasaccharide repeating unit of the capsular polysaccharide of Klebsiella serotype 11, K11PS, comprises the following sequence: [----3)-beta-D-GlcpA-(1----3)-alpha-D-Galp-(1----3)-beta-D-Glcp-(1 ----] with a 4,6-O-(1-carboxyethylidene)-alpha-D-galactopyranosyl residue linked to O-4 of the glucuronic acid residue. Octasaccharide (OS) derived from K11PS by bacteriophage phi 11-associated glycanase, was coupled to bovine serum albumin and to keyhole limpet hemocyanin. The immunogenicity of various antigens after intraperitoneal immunization was studied by measuring the levels of circulating antibodies. Injection of BALB/c mice with K11PS resulted in induction of 2-mercaptoethanol-sensitive immunoglobulin M antibodies. The responses observed in BALB/c nu/nu mice and in male (CBA/N X C3H/HeN)F1 mice indicate that K11PS is a thymus-independent type 2 antigen. Immunization of BALB/c mice with either OS-bovine serum albumin or OS-keyhole limpet hemocyanin resulted in the induction of circulating 2-mercaptoethanol-resistant immunoglobulin G antibodies. Results in BALB/c nu/nu mice indicate that the OS-protein conjugates are thymus-dependent antigens. Since the OS-keyhole limpet hemocyanin conjugate induced antibodies in both (CBA/N X C3H/HeN)F1 females and males, we propose to refer to this kind of antigen as a thymus-dependent type 1 antigen, whereas OS-bovine serum albumin, which evoked immunoglobulins in (CBA/N X C3H/HeN)F1 females only, can be referred to as a thymus-dependent type 2 antigen.

Human malignant T cells capable of inducing an immunoglobulin class switch

Evidence is presented for the existence of a "switch" T cell derived from a patient with mycosis fungoides/Sezary's syndrome. The serum immunoglobulin profile in this patient revealed high IgG and IgA but no detectable IgM. Peripheral blood mononuclear cells from this patient secreted only IgG and IgA in the presence of pokeweed mitogen. T cells (Trac) co-cultured with normal allogeneic non-T cells and pokeweed mitogen resulted in only IgG and IgA PFC, with little or no IgM secretion. There was no evidence of active suppression of IgM. Rather, these T cells appeared to induce an Ig class switch from IgM to IgG and IgA, when co-cultured with mu+ tonsillar B cells. Further evidence was obtained using mononuclear cells derived from a patient with immunodeficiency and hyper-IgM, a syndrome characterized by a lack of IgG and IgA secretion. The addition of Trac cells to either peripheral blood mononuclear cells or non-T cells from a patient with hyper-IgM syndrome resulted in new secretion of IgG, with a concomitant decrease in IgM secretion, whereas control T cells were not effective in inducing secretion of any isotype other than IgM. Isolated Tac+ T cells from Trac appear to be responsible for this effect.

Adjuvant effect of bacterial LPS and/or alum precipitation in responses to polysaccharide and protein antigens

A conjugate of a hapten (NIP) and a strongly antigenic protein chicken gamma globulin (CGG), when injected in soluble form into mice, induced weak primary responses, as weak as responses induced by conjugates of NIP (or other haptens) to polysaccharides Ficoll or alpha (-1-6) dextran. Mean concentrations of anti-hapten antibodies on day 14 varied within the range of 37-105 micrograms/ml (C57BL mice) or 14-38 micrograms/ml (CBA mice). The NIP-protein conjugate administered in alum-precipitated form induced 100 times higher primary antibody responses. Alum-precipitation of NIP-Ficoll made it a modestly stronger antigen than soluble NIP-Ficoll. When lipopolysaccharide (LPS) was injected together with any of the soluble antigens, the mice produced plenty of anti-hapten antibodies regardless of whether the antigen was hapten-polysaccharide or hapten-protein conjugate. Concentrations on day 14 varied from around 400 micrograms/ml to approximately 1600 micrograms/ml. LPS had a similar adjuvant effect on antidextran responses. LPS alone induced a polyclonal immunoglobulin production, and the immunoglobulin produced included 'anti-NIP' or 'anti-dextran' detectable in the solid phase antibody assay. These 'antibodies' induced by LPS alone were almost totally mercapto-ethanol-sensitive and poorly detectable by Farr assay or the bacteriophage assay. The response to the LPS+antigen combination was specific for the antigen and included both mercapto-ethanol-sensitive and resistant antibodies.