Types of tolerance seen in autoreactive phosphocholine-specific B cells are dependent on the idiotype of the receptors expressed.

Phosphocholine (PC) is the immunodominant epitope found on the surface of a number of microorganisms, including Streptococcus pneumoniae (SPn), and is thought to play a vital role in the pathogenesis of SPn. B cells expressing M167Hκ24L immunoglobulin receptors specific for PC have been shown to be autoreactive in that they undergo clonal deletion in both X-linked immune-deficient and Rag(-/-) mice. We have now shown that B cells expressing M603Hκ8L PC-specific receptors also delete in Rag(-/-) mice, whereas those expressing T15Hκ22L transgenes do not delete. However, T15Hκ22L B cells are lost in normal heterozygous transgenic mice because they cannot compete with normal B cells. These data indicate that M167Hκ24L and M603Hκ8L PC-specific B cells are recognizing an autoantigen expressed on membranes which causes them to downregulate their receptors and clonally delete, while T15Hκ22L B cells are tolerized by a soluble form of PC-antigen which results in their being trapped in the spleen. Thus, the types of tolerance seen in autoreactive PC-specific B cells are dependent on the idiotype of the receptors expressed.

2 BCR or NOT 2 BCR - receptor dilution: a unique mechanism for preventing the development of holes in the protective B cell repertoire.

The clonal selection theory and the associated corollaries have had a major influence in shaping our thinking about lymphoid cell development as well as how these cells respond to antigenic challenges. Among these concepts are that a single B cell expresses a single receptor with a single antigen specificity. While these hypotheses have proven invaluable in expanding our understanding of immune response, over time numerous observations have been made that suggest that the single cell, single receptor, single specificity model is not absolute. In this manuscript, we review this literature as it pertains to B cells and provide a summary that supports the notion that in certain situations, the over-arching rules by which we consider development and response of immune cells may be compromised. The result of compromising allelic and isotype exclusion is a small but real population of dual receptor expressing B cells. A number of mechanisms that have been proposed for generating these dual expressing B cells are presented and discussed. We also consider the negative implications of dual receptor expression on regulating and controlling autoreactive B cell populations as well as its beneficial contributions to preserving essential receptor specificities and thereby preventing the development of holes in the immune repertoire. Previously, the dual receptor expressing population has received relatively little attention. Improvements in the tools available to examine individual B cell populations have resulted in our identification of and discrimination between novel populations of B cells, including novel dual receptor expressing populations. This combined with continuing increases in our understanding of how the immune repertoire relates to a protective immune response will strengthen and further define this novel aspect of immune cell development.

Dual isotype expressing B cells [kappa(+)/lambda(+)] arise during the ontogeny of B cells in the bone marrow of normal nontransgenic mice.

Central to the clonal selection theory is the tenet that a single B cell expresses a single receptor with a single specificity. Previously, based on our work in anti-phosphocholine transgenic mouse models, we suggested that B cells escaped clonal deletion by coexpression of more than one receptor on their cell surface. We argued that "receptor dilution" was necessary when: (i) the expressed immunoglobulin receptor is essential for immune protection against pathogens and (ii) this protective receptor is autoreactive and would be clonally deleted, leaving a hole in the B cell repertoire. Here, we demonstrate that dual isotype expressing B cells arise during the normal ontogeny of B cells in the bone marrow and populate both the spleen and peritoneal cavity of nontransgenic mice. Furthermore, single cell analysis of the expressed immunoglobulin light chains suggests that receptor editing may play a role in the generation of a significant fraction of dual isotype expressing B cells.

The M603 idiotype is lost in the response to phosphocholine in terminal deoxynucleotidyl transferase-deficient mice.

The majority of anti-phosphocholine (PC) antibodies induced by the PC epitope in Proteus morganii (PM) express the M603 idiotype (id), which is characterized by an invariant Asp to Asn substitution at the V(H):D(H) junction. To elucidate the molecular basis by which M603-like B cells acquire the mutations resulting in this invariant substitution, we analyzed the immune response to PC-PM in terminal deoxynucleotidyl transferase (TdT) gene knockout (KO) mice. In the absence of TdT, T15-id antibodies comprised 80-100% of the primary response to PC-PM. Less than 10% of the response in wild-type mice is T15-id(+). In TdT KO mice, the secondary response to PC-KLH was higher than in wild-type mice and was dominated by the germ-line T15-id. About 10% of this response, in both TdT KO and wild-type mice, comprised M167-id(+) antibodies. Additionally, none of the functionally rearranged V1/DFL16.1/J(H)1 cDNA isolated from PC-PM-immunized TdT KO mice showed the Asp/Asn substitution characteristic of PC-binding, PC-PM-induced M603-like antibodies. These data indicate that production of M603-id antibody is TdT dependent, while generation of M167-id antibody is TdT independent, and that in the absence of competition from M603-like B cells, T15-id B cells can respond to PC-PM.

T15-idiotype-negative B cells dominate the phosphocholine binding cells in the preimmune repertoire of T15i knockin mice.

T15i knockin (KI) mice express a H chain that is encoded by a rearranged T15 VDJ transgene which has been inserted into the J(H) region of chromosome 12. This T15H chain combines with a kappa22-33 L chain to produce a T15-Id+ Ab having specificity for phosphocholine (PC). Inasmuch as T15-Id+ Abs dominate the primary immune response to PC in normal mice, it was surprising to find that 80% of the PC-dextran-binding B cells in unimmunized homozygous T15i KI mice were T15-Id-. Analysis of L chains expressed in these T15-Id-, PC-specific B cells revealed that two L chains, kappa8-28 and kappa19-15, were expressed in this population. The V(kappa) region of these L chains was recombined to J(kappa)5, which is typical of L chains present in PC-specific Abs. When T15i KI mice were immunized with PC Ag, T15-Id+ B cells expanded 6-fold and differentiated into Ab-secreting cells. There was no indication that the T15-Id- B cells either proliferated or differentiated into Ab-secreting cells following immunization. Thus, T15-Id- B cells dominate the PC-binding population, but they fail to compete with T15-Id+ B cells during a functional immune response. Structural analysis of T15H:kappa8-28L and T15H:kappa19-15L Abs revealed L chain differences from the kappa22-33 L chain which could account for the lower affinity and/or avidity of these Abs for PC or PC carrier compared with the T15-Id+ T15H:kappa22-33L Ab.