Frequency analysis of the antibody specificity repertoire of mitogen-reactive B cells and "spontaneously" occurring "background" plaque-forming cells in nude mice

Tipping the Scale: Atheroprotective IgM-Producing B Cells in Atherosclerosis

Atherosclerosis is a chronic inflammatory disease whose progression is fueled by proinflammatory moieties and limited by anti-inflammatory mediators. Whereas oxidative damage and the generation of oxidation-specific epitopes that act as damage-associated molecular patterns are highly inflammatory, IgM antibodies produced by B-1 and marginal zone B cells counteract unrestricted inflammation by neutralizing and encouraging clearance of these proinflammatory signals. In this review, we focus on describing the identities of IgM-producing B cells in both mice and humans, elaborating the mechanisms underlying IgM production, and discussing the potential strategies to augment the production of atheroprotective IgM. In addition, we will discuss promising therapeutic interventions in humans to help tip the scale toward augmentation of IgM production and to provide atheroprotection.

B-1 plasma cells require non-cognate CD4 T cell help to generate a unique repertoire of natural IgM

Evolutionarily conserved, "natural" (n)IgM is broadly reactive to both self and foreign antigens. Its selective deficiency leads to increases in autoimmune diseases and infections. In mice, nIgM is secreted independent of microbial exposure to bone marrow (BM) and spleen B-1 cell-derived plasma cells (B-1PC), generating the majority of nIgM, or by B-1 cells that remain non-terminally differentiated (B-1sec). Thus, it has been assumed that the nIgM repertoire is broadly reflective of the repertoire of body cavity B-1 cells. Studies here reveal, however, that B-1PC generate a distinct, oligoclonal nIgM repertoire, characterized by short CDR3 variable immunoglobulin heavy chain regions, 7-8 amino acids in length, some public, many arising from convergent rearrangements, while specificities previously associated with nIgM were generated by a population of IgM-secreting B-1 (B-1sec). BM, but not spleen B-1PC, or B-1sec also required the presence of TCRαβ CD4 T cells for their development from fetal precursors. Together, the studies identify important previously unknown characteristics of the nIgM pool.

Natural IgM prevents autoimmunity by enforcing B cell central tolerance induction

It is unclear why selective deficiency in secreted (s)IgM causes Ab-mediated autoimmunity. We demonstrate that sIgM is required for normal B cell development and selection. The CD5(+) B cells that were previously shown to accumulate in body cavities of sIgM(-/-) mice are not B-1a cells, but CD19(int), CD43(-), short-lived, BCR signaling-unresponsive anergic B-2 cells. Body cavity B-1 cells were >10-fold reduced, including VH11(+) and phosphotidylcholine-specific B-1a cells, whereas splenic B-1 cells were unaffected and marginal zone B cells increased. Follicular B cells had higher turnover rates, survived poorly after adoptive transfer, and were unresponsiveness to BCR stimulation in vitro. sIgM bound to B cell precursors and provided a positive signal to overcome a block at the pro/pre-B stage and during IgVH repertoire selection. Polyclonal IgM rescued B cell development and returned autoantibody levels to near normal. Thus, natural IgM deficiency causes primary autoimmune disease by altering B cell development, selection, and central tolerance induction.

Natural IgM is produced by CD5- plasma cells that occupy a distinct survival niche in bone marrow

Natural IgM is constitutively present in the serum, where it aids in the early control of viral and bacterial expansions. Natural IgM also plays a significant role in the prevention of autoimmune disease by promoting the clearance of cellular debris. Nevertheless, the origins of natural IgM have not been precisely defined. Previous studies focused on the role of CD5(+) B1 cells in the production of natural IgM, but we show in this article that a discrete population of CD5(-) IgM plasmablasts and plasma cells in the bone marrow (BM) produces the majority of serum IgM in resting mice. These Ab-secreting cells (ASC) originate from peritoneal cavity-resident cells, because transfer of peritoneal cells completely restores serum IgM and the specific compartment of BM ASC in Rag1-deficient mice. We show that BM natural IgM ASC arise from a fetal-lineage progenitor that is neither B1a nor B1b, and that this IgM ASC compartment contains a substantial fraction of long-lived plasma cells that do not occupy the IgG plasma cell survival niche in the BM; instead, they are supported by IL-5. In summary, we identified the primary source of natural IgM and showed that these ASC are maintained long-term in a unique survival niche within the BM.

B-1 cells in the bone marrow are a significant source of natural IgM

Natural IgM antibodies secreted in the absence of antigenic challenge are important contributors to antimicrobial immunity and tissue homeostasis. Early studies identified BM and, to a lesser extent the spleen, as main tissue sources of this spontaneously secreted IgM. However, the responsible B-cell subset has never been identified. Using multicolor flow cytometry, cell sorting and chimeric mice in which B-1 and B-2 cells and their secreted antibodies are distinguished by their Ig-allotype, we unequivocally identify the natural IgM-secreting cells in spleen and, for the first time, in the BM as IgM(+) IgD(lo/-) CD19(hi) CD43(+) CD5(+/-) B-1 cells. The newly identified population of BM B-1 cells shows many of the phenotypic characteristics of splenic B-1 cells but is distinct from B-1 cells in the peritoneal cavity, which generate at best very small amounts of IgM. Antibody-secreting spleen and BM B-1 cells are distinct also from terminally differentiated plasma cells generated from antigen-induced conventional B cells, as they express high levels of surface IgM and CD19 and lack expression of CD138. Overall, these data identify populations of non-terminally differentiated B-1 cells in spleen and BM as the most significant producers of natural IgM.

The primary structure and specificity determining residues displayed by recombinant salmon antibody domains

Previously, single chain fragments of salmon (Salmo salar L.) immunoglobulin variable regions (scFv) were isolated by reactivity towards trinitrophenyl (TNP) or fluorescein (FITC) using phage display technology. The fine specificity of six scFv clones were analysed by ELISA, while the primary structure was determined by DNA sequencing. In addition, preliminary models of one anti-TNP and one anti-FITC clone were built. Here, a follow-up analysis of the primary and tertiary structure of all six clones is focused on the structural basis for hapten specificity. Tertiary structure was analysed by molecular modelling of the antigen combining site. The analysis shows that reactivity to each hapten is maintained by a number of different combinations of VH, D, JH and VL sequences. Accordingly, various sizes of CDR3 on both the heavy and light chain and CDR2 of IgH may support TNP binding. Due to variability of the antigen combining site each clone probably has a distinct binding affinity. However, a feature common among the four scFv antibodies that recognise TNP is a positively charged Arg in CDR2 of either the heavy or light chain. In the majority of the anti-TNP clones localisation of this side-chain is stabilised by a negatively charged Asp in LCDR1. In addition, a Trp in LCDR3 is conserved in all the anti-TNP clones. Also, the anti-FITC clones display a Trp in the LCDR3, suggesting its participation in binding of FITC as well. In combination with a large aromatic amino acid near the N-terminus of HCDR2 and a positively charged Arg in CDR1, these residues probably determine both specificity and affinity towards the FITC moiety.

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.

Early development of Ig-secreting cells in young of germ-free BALB/c mice fed a chemically defined ultrafiltered diet

The influence of antigenic stimulation on the early development of the "spontaneously" occurring ("background") IgM-, IgG-, and IgA-secreting cells has been studied in mice. To evaluate the effect of such exogenous stimulation by an evolving microbial microflora, the young of BALB/c mice that were kept under germ-free conditions and fed a low molecular weight chemically defined synthetic diet (GF-CD) were compared with the young of conventional BALB/c mice fed natural ingredients (CV-NI). The young were first suckling maternal milk and between Days 15 and 18 changed to the same diet as their parents. Background Ig-secreting cells in the spleen were enumerated in the protein A plaque assay. The specificity repertoire of the IgM-secreting cells was determined with plaque assays specific for sheep red blood cells (SRBC) that were haptenized with different concentrations of nitroiodophenyl (NIP), 4-hydroxy-3.5-dinitrophenyl (NNP), and 2,4,6-trinitrophenyl (TNP). The results show that during the first few weeks of life the numbers of background IgM-, IgG-, and IgA-secreting cells in the spleen develop faster in CV-NI mice than in GF-CD mice. At 4 weeks of age equal numbers of IgM- and IgG-secreting cells were found in both groups of mice, but the number of IgA-secreting cells remained reduced in GF-CD mice during the whole period of observation. The frequencies of IgM-secreting cells specific for the differently haptenized SRBC were the same in both groups of mice during the observation period of 10 weeks. This suggests that the ontogenetic appearance of IgM-, IgG-, and IgA-secreting cells in the spleen, and the specificity repertoire of the IgM-secreting cells, as far as was tested in our panel, is independent of exogenous antigenic and/or mitogenic stimulation. However, during neonatal development the rate of development of the background Ig synthesis is enhanced by environmental antigenic stimulation.