Analysis of the human CD5- CD45RAlow B-cell subset

Elevation of CD5+ B lymphocytes in schizophrenia

BACKGROUND

A variety of immunologic alterations have been observed in patients with schizophrenia. These findings have lent support to theories that autoimmune mechanisms may be important in some patients with the illness. The CD5+ B lymphocyte, a B-cell subset associated with autoimmune disease, has been the subject of two previously published studies yielding disparate results.

METHODS

In this study, we used immunofluorescent flow cytometry to measure CD5+ B cells, total B and T cells, and CD4 and CD8 subsets in patients with schizophrenia and in normal control subjects.

RESULTS

A significantly higher percentage of patients with schizophrenia, relative to normal control subjects, exhibited an elevated level of CD5+ B cells (27.6% vs 6.7%). Antipsychotic withdrawal had no effect on CD5+ B-cell levels, suggesting that medication effects were not the cause of this difference. No other studied lymphocyte subsets differed between the two groups.

CONCLUSIONS

A subset of patients with schizophrenia have elevated levels of CD5+ B cells. This finding replicates an earlier study by another group and provides further evidence suggestive of autoimmune manifestations in schizophrenia.

CD5+ and CD5- B1-like lymphocytes in healthy guinea pig

Spleen, lymph node, and peripheral blood lymphocytes from healthy guinea pigs (gp) were examined for their ability to produce polyreactive autoantibodies to a battery of self-antigens and to cryptic determinants (phosphatidylcholine) on bromelain-treated mouse red blood cells (Br-MRBC). The mouse monoclonal antibody (Mab) 8BE6 anti-gp pan-T (CD5) marker was used for identification of CD5+ B1 cells by the plaque-forming assay (PFC), immunofluorescence, complement-mediated cytotoxicity, and immunocytochemistry. The detection of CD5+ cells by the 8BE6 Mab depended on the method used. They were better demonstrated by cytolysis and immunocytochemistry than by FACS analysis. By the latter method, the level of the CD5+ B cell subpopulation was associated neither with the age of the gp nor with the organ examined. Similarly wide ranges of PFC were detected in untreated or LPS-treated animals regardless of age and organ. The vast majority of the LPS-stimulated IgM antibody-secreting B lymphocytes reacting with the Br-MRBC, and those producing natural autoantibodies, did not bind the 8BE6 Mab.

Structure and function of natural antibodies

Natural antibodies arise independently of known antigenic stimulation, are mostly IGM, polyreactive, and are generally encoded by V genes in germline configuration. Polyreactive IgM natural antibodies are produced by mainly B-1 cells which account for most of the B cell repertoire in the fetus and neonate, and possibly play a major role in the development and physiology of the human B cell repertoire. Although endowed with self-reactivity, natural antibodies also bind exogenous antigens [73, 74]. Exposure to environmental antigens is not necessary for the emergence of natural antibody-producing cell precursor clones to exogenous antigens, as suggested by the significant population of B cells capable of producing antibodies to a variety of bacterial antigens in germ-free animals. Because of their ability to bind a variety of exogenous antigens, including those on bacteria and viruses, natural antibodies play a major role in the primary line of defense against infections. A central issue related to the understanding of the physiopathologic roles of natural antibodies is whether precursors of cells producing natural antibodies, B-1a and B-1b lymphocytes, are capable of undergoing an antigen-driven clonal selection process, thereby producing autoantibodies with a high affinity for the selecting antigen. In this respect, we have clearly established that B-1 cells can express a hypermutation mechanism similar to that of conventional (B-2) cells. Furthermore, we have shown by gene shuffling, site-directed mutagenesis, and in vitro human Ig gene expression, that the main structural correlate for antibody polyreactivity is provided by the somatically generated H chain CDR3. We have also shown that this Ig V region provides the main structural correlate for antigen-binding in monoreactive antigen-induced autoantibodies. These findings in the human are at the basis of our proposed structure-function model in which the antigen binding features of the germline template antibody are dictated by the somatically generated H chain CDR3, and perhaps, but at a lower degree, L chain CDR3; the point-mutation changes underlying the antigen-driven affinity maturation process would impact mainly the Ig V gene encoded segments. This structure-function model is being tested in our laboratory by analyzing the antigen binding activity of somatically mutated polyreactive autoantibodies that have been structurally reverted to their original putative unmutated configuration. Precise identification of the Ig gene and/or somatic recombination products mediating recruitment of unmutated B cell clonotypes, as well as those that are preferentially modified by an antigen-dependent selection process, should further our understanding of the mechanisms that shape the B cell repertoire in development and disease.

Autoimmunity-prone B-1 (CD5 B) cells, natural antibodies and self recognition

The delineation of distinct subsets committed to the production of antibodies with different antigen-binding activities supports the view of a compartmentalization and specialization of function in the B cell repertoire and is consistent with the hypothesis of a developmentally layered immune system; as originally proposed by Herzenberg and Herzenberg. On the basis of the data by Solvason and Kearney in the human fetus and our data in the adult, and in agreement with the findings of Herzenberg et al. and Hardy et al. in the mouse, we propose that the human B cell repertoire includes at least three distinct B cell subsets: B-1a cells, which develop from progenitors in the fetal splanchnic district, namely the omentum, and are maintained in adult life by virtue of their self-replenishing nature; B-1b cells, progenitors of which can be found in the splanchnic district and, perhaps, adult bone marrow; and, finally, B-2 cells, which arise in the fetal liver and are continuously replenished in adult life by progenitors in the bone marrow (Figure 5). The different B cells types are distinguished by their differential expression of surface CD5 and, perhaps, CD11b and CD14, their differential expression of CD5 mRNA, and the different classes and specificities of the Ig they produce (Figure 5). B-1 lymphocytes play a major role in autoimmunity and constitute the physiological equivalent of the neoplastic forms in various lymphoproliferative disorders, such as CLL and SLL, which are often associated with the production of monoclonal antibodies to self antigens. Human B-1a (CD5+ B) and B-1b (CD5- CD45RAlo B) cells are responsible for the production of natural (polyreactive and monoreactive) antibodies in the fetus, neonate, and adult, and can give rise to the autoantibody-producing cells characteristic of several autoimmune disease states. Our recent findings suggest that while in healthy subjects the majority of natural polyreactive antibodies is encoded in V genes in germline configuration, some polyreactive antibodies are encoded in somatically mutated V genes, in a fashion consistent with an antigen-driven process of selection of such mutations. The nature of the antigen(s) involved in these selection processes remains to be determined. Under possibly different circumstances, the application of an antigen-driven process of clonal selection to B-1a and/or B-1b cells, previously committed to natural antibody production, can result in the generation of monoreactive high affinity and possibly pathogenic autoantibodies (Figures 5A and 5B).(ABSTRACT TRUNCATED AT 400 WORDS)