Targeted Expression of Major Histocompatibility Complex (MHC) Class II Molecules Demonstrates that Dendritic Cells Can Induce Negative but Not Positive Selection of Thymocytes In Vivo

A new procedure for rapid isolation of dendritic cells (DC) was devised, involving collagenase digestion of tissues, dissociation of lymphoid-DC complexes, selection of light-density cells, then depletion of lymphocytes and other non-DC by treatment with a mixture of lineage- specific monoclonal antibodies (mAbs) and removal with anti- immunoglobulin-coupled magnetic beads. This enriched population (approximately 80% DC) was further purified when required by fluorescence-activated cell sorting for cells expressing high levels of class II major histocompatibility complex (MHC). The isolated DC were characterized by immunofluorescent staining using a panel of 30 mAbs. Thymic DC were surface positive for a number of markers characteristic of T cells, but they were distinct from T-lineage cells in expressing high levels of class II MHC, in lacking expression of the T cell receptor (TCR)-CD3 complex, and having TCR beta and gamma genes in germline state. Splenic DC shared many markers with thymic DC, but were negative for most T cell markers, with the exception of CD8. A substantial proportion of DC from both thymus and spleen expressed CD8 at high levels, comparable with that on T cells. This appeared to be authentic CD8, and was produced by the DC themselves, since they contained CD8 alpha mRNA. Thymic DC presented both the CD8 alpha and beta chains on the cell surface (Ly-2+3+), although the alpha chain was in excess; the splenic DC expressed only the CD8 alpha chain (Ly-2+3-). It is suggested that the expression of CD8 could endow certain antigen- presenting DC with a veto function.

The MHC class II gene Aa was disrupted by targeted mutation in embryonic stem (ES) cells derived from C57BL/6 mice to prevent expression of MHC class II molecules. Contrary to previous reports, the effect of the null-mutation on T cell development was investigated in C57BL/6 mice, which provide a defined genetic background. The complete lack of cell surface expression of MHC class II molecules in B6-Aa0/Aa0 homozygous mutant mice was directly demonstrated by cytofluorometric analysis using anti-Ab and anti-Ia specific mAbs. Development of CD4+CD8- T cells in the thymus was largely absent except for a small population of thymocytes expressing high levels of CD4 together with low amounts of CD8. The majority of these cells express the TCR at high density. Although mature CD4+CD8- T cells were undetectable in the thymus, some T cells with a CD4+CD8-TCRhigh phenotype were found in lymph nodes and spleen. Peripheral T cells from the mutant mice can be polyclonally activated in vitro with the mitogen concanavalin A. However, they could not be stimulated with staphylococcal enterotoxin B in autologous lymphocyte reactions, thereby demonstrating the absence of MHC class II expression in these mice. Peripheral B cells in B6-Aa0/Aa0 mutants were functional and responded to the T cell independent antigen levan by the production of antigen-specific IgM antibodies similar to wild-type cells. The B6-Aa0/Aa0 mutant mice described in this study represent an important tool to investigate the involvement of MHC class II molecules in lymphocyte maturation and the immune response.

Almost by definition, negative selection of T and B lymphocytes cannot be absolute. Given that both sets of receptors are derived by stochastic processes, recognition of epitopes by lymphocyte receptors will not be an all or none affair but a relative one. Too effective a mechanism of negative selection would have resulted in deletion of the whole repertoire, as all specificities would have cross-reacted with some self-epitope at least to some degree. This review has documented some of the influences impacting on emerging T and B cell repertoires that result in a removal of the most dangerous self-reactive cells and the progressive quantitative and qualitative increase, through positive clonal selection, of other cells specific for the actual foreign antigens encountered by each individual. T and B lymphocytes pass through a stage where their natural reaction to antigen is one of negative selection and on to a later stage where the cell is more likely to become activated. Geography plays a role in this; the primary lymphoid organs are designed largely to exclude foreign antigens and to present self-antigens, whereas the secondary lymphoid organs are designed to filter out and concentrate foreign material and to promote costimulatory intercellular immune interactions. Ontogeny of individual cells also plays its role, probably through the progressive assembly of the full receptor signaling machinery, incomplete arrays promoting a negative rather than a positive signal. However, the differing susceptibilities of immature and mature cells to silencing by deletion or anergy are relative rather than absolute. Negative signaling may involve immediate or somewhat delayed death of the anti-self-cell, and in some cases the bad cell may have the chance of editing its receptor to create one lacking anti-self-reactivity. Alternatively, the cell may receive a nonlethal down-regulatory signal and may be induced into a state of anergy. Such anergic cells may have a reduced life span, showing that anergy and deletion may shade into each other. Upon the removal of antigen (an unlikely event for cells anergic to an authentic self-antigen), the state of anergy is reversible. The strength of the receptor cross-linking signal may chiefly determine whether deletion (strong cross-linking) or anergy (weaker cross-linking) supervenes. Some lymphocytes with self-reactivity ignore the self-antigen in question because of low affinity, poor accessibility, lack of suitable presentation, or absence of appropriate help.(ABSTRACT TRUNCATED AT 400 WORDS)