The T/B cell interaction involved in induction of the mouse IgG2ab suppression is restricted by major histocompatibility complex class I, but not class II molecules

The strength of B cell immunity in female rhesus macaques is controlled by CD8+ T cells under the influence of ovarian steroid hormones

To understand more clearly how mucosal and systemic immunity is regulated by ovarian steroid hormones during the menstrual cycle, we evaluated the frequency of immunoglobulin- and antibody-secreting cells (ISC, AbSC) in genital tract and systemic lymphoid tissues of normal cycling female rhesus macaques. The frequency of ISC and AbSC was significantly higher in tissues collected from animals in the periovulatory period of the menstrual cycle than in tissues collected from animals at other stages of the cycle. The observed changes were not due to changes in the relative frequency of lymphocyte subsets and B cells in tissues, as these did not change during the menstrual cycle. In vitro, progesterone had a dose-dependent inhibitory effect, and oestrogen had a dose-dependent stimulatory effect on the frequency of ISC in peripheral blood mononuclear cell (PBMC) cultures. The in vitro effect of progesterone and oestrogen on ISC frequency could not be produced by incubating enriched B cells alone with hormone, but required the presence of CD8+ T cells. Following oestrogen stimulation, a CD8+ enriched cell population expressed high levels of IFN-gamma and IL-12. The changes in B cell Ig secretory activity that we document in the tissues of female rhesus macaques during the menstrual cycle is due apparently to the action of ovarian steroid hormones on CD8+ T cells. Thus, CD8+ T cells control B cell secretory activity in both mucosal and systemic immune compartments. Understanding, and eventually manipulating, the CD8+ regulatory cell-B cell interactions in females may produce novel therapeutic approaches for autoimmune diseases and new vaccine strategies to prevent sexually transmitted diseases.

Self peptides and the peptidic self

Twenty years ago, antigenic and self peptides presented by MHC molecules were absent from the immunological scene. While foreign peptides could be assayed by immune reactions, self peptides, as elusive and invisible as they were at the time, were bound to have an immunological role. How self peptides are selected and presented by MHC molecules, and how self MHC-peptide complexes are seen or not seen by T cells raised multiple questions particularly related to MHC restriction, alloreactivity, positive and negative selection, the nature of tumor antigens and tolerance. These issues were addressed in the "peptiditic self model" (1986) and subsequent hypothesis. They are retrospectively and critically reviewed here in the context of our current understanding of these major immunological phenomena.

Role of CD40 in a T cell-mediated negative regulation of Ig production

To investigate the possible role of CD40 in a negative regulation of Ig production, we used the mouse Ig allotype suppression model. T splenocytes from IGH(a/a) mice are able in vivo to totally and chronically inhibit the production of IgG(2a)(b) (IgG2a from the IGH(b) haplotype). Accordingly, postnatal transfer of IGH(a/a) T splenocytes into histocompatible IGH(a/b) F(1) or congenic IGH(b/b) mice leads to a characteristic IgG(2a)(b) suppression. The helper action of anti-IgG(2a)(b) CD4(+) T cells is required for the recruitment of anti-IgG(2a)(b) CD8(+) T suppression effectors. The latter use perforin (pore-forming protein, Pfp)- and/or Fas-dependent cytotoxic pathways to continuously eliminate B cells recently committed to IgG(2a)(b) production. In the present study we first showed that in vivo agonistic anti-CD40 mAb treatment of IGH(a/a) mice, deprived of their CD4(+) T cell compartment, could bypass the help of Ig allotype-specific CD4(+) T cells and generate CD8(+) T effector cells able to strongly inhibit IgG(2a)(b) production. This result demonstrates the usefulness of CD40 triggering in setting up an immune regulatory mechanism. Furthermore, with regard to the suppression-effector mechanism, we demonstrated that B cell CD40 expression was required for full suppression establishment via the Fas-dependent pathway. Indeed, IGH(a/a) PFP(degrees/degrees) T cells (using exclusively the Fas pathway) induced full IgG(2a)(b) suppression against IGH(b/b) CD40(+/+) B cells, but only partial inhibition of IgG(2a)(b) production against IGH(b/b) CD40(degrees/degrees) B cells. This finding provides the first demonstration of direct involvement of B cell CD40 expression in in vivo negative control of an Ig production.

Central tolerance induction in natural immunoglobulin-allotype-specific T cells

While self toleance is induced to IgG(b)(2a) in Igh(b / b) mice, an anti-IgG(b)(2a) T cell activity emerges in their Igh(a / a) congenic counterparts. This activity is revealed by postnatal transfer of Igh(a / a) T splenocytes into Igh(a / b) F(1), in which total suppression of IgG(2a)(b) expression is established. Here, we sought to determine whether the natural T cell unresponsiveness to IgG(2a)(b) in Igh(b / b) mice involved a central tolerance. Based on the kinetics of postnatal thymic C(gamma2a)(b) gene expression in Igh(b / b) mice, we transplanted thymi from Igh(b / b) donors of diverse ages into tolerogen-free Igh(a / a) nu / nu recipients. The state of T cell tolerance or responsiveness to IgG(2a)(b) in these reconstituted nu / nu hosts was determined by monitoring the capacity of their splenocytes to induce suppression in Igh(a / b) F(1). These experiments demonstrated that: (i) in the Igh(a / a) nu / nu recipients of adult Igh(b / b) thymi, 33 to 65 % T splenocytes were from nu / nu recipient origin, but these peripheral Igh(a / a) T cells were rendered tolerant to IgG(2a)(b) during their differentiation through the adult Igh(b / b) thymi, (ii) circulating IgG(2a)(b) was not a prerequisite for this tolerance induction, (iii) Igh(b / b) thymic epithelium was unable to induce tolerance to IgG(2a)(b) and (iv) IgG(2a)(b)-producing / presenting cells, colonizing the Igh(b / b) thymi, were certainly responsible of full tolerance induction to IgG(2a)(b).

Non-overlapping Fas- and BCL-2-regulated death pathways in IgG2a(b)-producing B cells

Using perforin (Pfp)- and/or Fas-dependent cytotoxic pathways, T splenocytes from Igh(a/a) mice are able in vivo to totally and chronically eliminate congenic Igh(b/b) B cells committed to IgG2a(b) production. This phenomenon leads to a characteristic absence of serum IgG2a(b) expression (IgG2a(b) allotype suppression) in, for instance, histocompatible Igh(a/b) or Igh(b/b) mice, having neonatally received such T cells. Because the study of the protective role of BCL-2 oncoprotein against Fas-mediated cell death has generated contradictory findings, we examined the possible impact of constitutive overexpression of transgenic human BCL-2 protein in Igh(b/b) B cells when the latter were exposed in vivo exclusively with the Fas-dependent, anti-IgG2a(b) T cell activity of Igh(a/a) Pfp(0/0) mice. We observed that, despite high intracellular expression of functional transgenic BCL-2 and no up-regulation of the principal BCL-2 inhibitors in whole Igh(b/b) B cells, total, chronic and specific IgG2a(b) suppression was exerted by Igh(a/a) Pfp(0/0) cytotoxic T cells. These data show that, in this model of negative regulation of Ig production, Fas- and BCL-2-regulated mechanisms belong to non-overlapping death pathways at the level of IgG2a(b)-producing B cells, targets of Igh(a/a) T cell-mediated cytotoxicity. Thus, in these mature B cells, the Fas signaling-directly operating via caspase 8-does not involve a mitochondria-dependent pathway regulated by BCL-2.

Evidence of Alternative or Concomitant Use of Perforin- and Fas-Dependent Pathways in a T Cell-Mediated Negative Regulation of Ig Production

To study the possible involvement of perforin (Pfp)- and/or Fas-dependent cytotoxicity pathways in a T cell-mediated negative regulation of Ig production, we used the T cell-induced Ig-allotype suppression model. T splenocytes from Igha/a mice, when neonatally transferred into histocompatible Igha/b F1 or Ighb/b congenic hosts, are intrinsically able to totally, specifically, and chronically suppress the production of IgG2a of the Ighb haplotype (IgG2ab). It has not been established whether the suppression effectors, which are anti-IgG2ab MHC class I-restricted CD8+ T cells, cytolyse IgG2ab+ B targets or whether they only silence Ig production. In this study, using T cells from Igha/a Pfp+/+ or Pfpo/o mice, the latter obtained by crossbreeding, and B cells from Ighb/b Fas+/+ or Faslpr/lpr (lymphoproliferation) mice in appropriate adoptive transfer models, we demonstrated that: 1) under blockage of the Pfp-mediated pathway, Igha/a T cells were still able to induce suppression against wild-type IgG2ab+ B cells, 2) IgG2ab+ B cells with impaired Fas expression were also subjected to suppression by WT Igha/a T splenocytes, and 3) the suppression establishment was totally inhibited when both Pfp- and Fas-dependent mechanisms were simultaneously blocked, i.e., when Igha/a Pfpo/o T cells were used to induce suppression against Ighb/b Faslpr/lpr B cells. These results provide the first demonstration of the existence of alternative or simultaneous use of the major cytotoxic mechanisms in a T cell-mediated down-regulation of an Ig production.

Inhibition of IgG2ab production by Ig allotype-specific T cells can Be mediated without T-B cell contact

The growth of IgG2ab-producing CB101 myeloma cells, subcutaneously or intraperitoneally inoculated into histocompatible BALB/c Igha mice sensitized against this Ig allotype, was delayed by 2-4 weeks compared to normal mice. While IgG2ab production was detected in the sera of 75-100% of normal mice, it was irreversibly inhibited in 100% of sensitized mice. IgG2ab suppression (IgG2ab sup) was also systematically obtained in sensitized but not normal recipients, implanted ip with a 0.1-micrometer-pore diffusion chamber (DC) containing CB101 cells. This time, the specific IgG2ab sup was reversible in vitro in the absence of anti-IgG2ab T cells. Adoptive transfer, of unfractionated or T but not B splenocytes from their sensitized counterparts into normal mice, 1 day before DC implantation, induced IgG2ab sup as well. These results indicate that, in these experimental circumstances, IgG2ab sup can also be mediated by diffusible suppressive factors produced by the effector T cells, without direct T-B-cell contact.

Impaired NK1.1+ T cells do not prevent the development of an IgE-dependent allergic phenotype

BACKGROUND

The induction of TH2 immune responses is critically dependent on initial IL-4. Although crucial, the source of this early IL-4 has not been identified. One candidate is a CD1 restricted NK1.1+ T cell subpopulation which is known to produce such early IL-4.

OBJECTIVES AND METHODS

The necessity of NK1.1+ T cells for the expression of an IgE-dependent phenotype was investigated in a NK1.1+ T cell deficient mouse model. The allergic phenotype was defined as immediate cutaneous hypersensitivity. It was induced by immunization of mice with ovalbumin. Mouse strains used were C57BL/6 mice and C57BL/6 mice homozygous for a targeted mutation of the beta2 microglobulin gene with consecutive loss of CD1 expression, which leads to a drastic reduction of NK1.1+ T cells. Manifestation of an allergic sensitization was assessed by intradermal allergen challenge after i.v. injection of Evans blue solution. The blue stained weal formations were quantified with the Bonitur method. In addition, the Th2 response was confirmed by the measurement of cytokines and serum immunoglobulins. The capability to produce early IL-4 was tested through the assessment of IL-4 mRNA shortly after a single challenge.

RESULTS

Wild type and mutated mice did not differ in any of the immunological parameters measured.

CONCLUSION

A single exposure to antigen with or without adjuvant induces early IL-4 production in C57BL/6 beta2m-/- mice. This early IL-4 is therefore independent of the presence of NK1.1+ T cells and functional MHC class I molecules and leads to IgE production and immediate cutaneous hypersensitivity.