Space, selection, and surveillance: setting boundaries with BLyS

The BLyS family of ligands and receptors governs B cell homeostasis by controlling survival, differentiation, and lifespan. This family consists of multiple receptors and ligands, allowing independent regulation of different B cell subsets by varying the combination and levels of receptors expressed. Multiple downstream signaling pathways are implicated in these activities, reflecting this receptor complexity as well as cross-talk with other B cell signaling systems. BLyS levels are associated with multiple forms of humoral autoimmunity and can modulate tolerogenic elimination at the transitional checkpoint. BLyS responsiveness thus balances peripheral selection against cell numbers, providing an elastic system that varies selective stringency based on homeostatic demands.     

Discovery of high-affinity peptide binders to BLyS by phage display

B lymphocyte stimulator (BLyS) is a tumor necrosis factor (TNF) family member and a key regulator of B cell responses. We employed a phage display-based approach to identify peptides that bind BLyS with high selectivity and affinity. Sequence analysis of first-generation BLyS-binding peptides revealed two dominant peptide motifs, including one containing a conserved DxLT sequence. Selected linear peptides with this motif were found to bind BLyS with K(D) values of 1-3 microM. In order to improve the binding affinity for BLyS, consensus residues flanking the DxLT sequence were seeded into a second-generation, BLyS affinity maturation library (BAML). BAML phage were subjected to stringent binding competition conditions to select for isolates expressing high-affinity peptide ligands for BLyS. Post-selection analysis of BAML peptide sequences resulted in the identification of a core decapeptide motif (WYDPLTKLWL). Peptides containing this core motif exhibited K(D) values as low as 26 nM, approximately 100-fold lower than that of first-generation peptides. A fluorescence anisotropy assay was developed to monitor the protein-protein interaction between BLyS labeled with a ruthenium chelate, and TACI-Fc, a soluble form of a BLyS receptor. Using this assay it was found that a BAML peptide disrupts this high-affinity protein-protein interaction. This demonstrates the potential of short peptides for disruption of high affinity cytokine-receptor interactions.     

Interaction of the TNF homologues BLyS and APRIL with the TNF receptor homologues BCMA and TACI

BLyS (also called TALL-1, THANK, or BAFF) [1] [2] [3] [4] is a member of the tumor necrosis factor (TNF) gene family that stimulates proliferation and immunoglobulin production by B cells. BLyS interacts with the TNF receptor (TNFR) homologue TACI (transmembrane activator and CAML-interactor) [5], and treatment of mice with a TACI-Fc fusion protein abolishes germinal center formation after antigenic challenge [6]. Here we report a novel interaction between BLyS and another TNFR homologue, BCMA (B cell maturation antigen) [7] [8]. Further, the TNF homologue APRIL [9], a close relative of BLyS, also bound to BCMA and TACI. BLyS or APRIL activated nuclear factor-kappaB (NF-kappaB) through TACI and BCMA, and each ligand stimulated immunoglobulin M (IgM) production by peripheral blood B cells. These results define a dual ligand-receptor system that may play an important role in humoral immunity.     

Production and purification of recombinant human BLyS mutant from inclusion bodies

B lymphocyte stimulator (BLyS), a member of the tumor necrosis factor superfamily, is an important regulator of B cell homeostasis. In BLyS-deficient mice, B cell development is severely perturbed. On the other hand, mice transgenic for BLyS developed autoimmune disorders, such as increased germinal center formation, production of autoantibodies, and Ig deposition in kidneys. The overexpression of BLyS was found in some human autoimmune diseases. These findings suggest that BLyS has a crucial role in the humoral immune response and may be a therapeutic target for some human autoimmune diseases. To construct and express the therapeutic vaccine BLyS, we coupled a foreign immunodominant T-helper epitope to the N terminus of BLyS (named recombinant BLyS mutant, rBLySM) and expressed rBLySM in Escherichia coli. We have developed a purification process of rBLySM from inclusion bodies. A step-down urea concentration strategy was applied to the rBLySM renaturation process. By this strategy, a stable yield of 4.5mg purified rBLySM per gram of cell paste could be obtained.     

B淋巴细胞刺激因子（BLyS）研究进展

B淋巴细胞刺激因子（BLyS）是1999年新发现的一种重要的细胞因子,属于肿瘤坏死因子(TNF)超家族成员.在体液免疫调控中起重要作用.它能强烈地刺激B淋巴细胞的增殖和分化并分泌大量免疫球蛋白(主要为IgM);在体外其过量表达能促进多种B系肿瘤细胞的生长.BLyS转基因小鼠出现严重的红斑狼疮样症状.对BLyS的基因和蛋白质结构、免疫调控功能、受体和信号通路及其在自身免疫性疾病和恶性肿瘤中的作用进行了综述.     

Competition for BLyS-mediated signaling through Bcmd/BR3 regulates peripheral B lymphocyte numbers

Striking cell losses occur during late B lymphocyte maturation, reflecting BcR-mediated selection coupled with requisites for viability promoting signals. How selection and survival cues are integrated remains unclear, but a key role for B lymphocyte stimulator (BLyS(TM); trademark of Human Genome Sciences, Inc.) is suggested by its marked effects on B cell numbers and autoantibody formation as well as the B lineage-specific expression of BLyS receptors. Our analyses of the B cell-deficient A/WySnJ mouse have established Bcmd as a gene controlling follicular B cell life span, and recent reports show Bcmd encodes a novel BLyS receptor. Here we show that A/WySnJ B cells are unresponsive to BLyS, affording interrogation of how Bcmd influences B cell homeostasis. Mixed marrow chimeras indicate A/WySnJ peripheral B cells compete poorly for peripheral survival. Moreover, in vivo BrdU labeling shows that (A/WySnJ x BALB/c)F(1) B cells have an intermediate but uniform life span, indicating viability requires continuous signaling via this pathway. Together, these findings establish the BLyS/Bcmd pathway as a dominant mediator of B cell survival, suggesting competition for BLyS/Bcmd signals regulates follicular B cell numbers.     

NF-kappa B1 p50 is required for BLyS attenuation of apoptosis but dispensable for processing of NF-kappa B2 p100 to p52 in quiescent mature B cells

B lymphocyte stimulator (BLyS), a TNF family protein essential for peripheral B cell development, functions primarily through attenuation of B cell apoptosis. In this study, we show that BLyS activates NF-kappaB through both classical and alternative pathways with distinct kinetics in quiescent mature B cells. It rapidly and transiently enhances the p50/p65 DNA binding activity and induces phosphorylation of IkappaBalpha characteristic of the classical NF-kappaB pathway, albeit maintaining IkappaBalpha at a constant level through ongoing protein synthesis and proteasome-mediated destruction. With delayed kinetics, BLyS promotes the processing of p100 to p52 and sustained formation of p52/RelB complexes via the alternative NF-kappaB pathway. p50 is dispensable for p100 processing. However, it is required to mediate the initial BLyS survival signals and concomitant activation of Bcl-x(L) in quiescent mature B cells ex vivo. Although also a target of BLyS activation, at least one of the A1 genes, A1-a, is dispensable for the BLyS survival function. These results suggest that BLyS mediates its survival signals in metabolically restricted quiescent B cells, at least in part, through coordinated activation of both NF-kappaB pathways and selective downstream antiapoptotic genes.     

Evolution in miniature: selection, survival and distribution of antigen reactive cells in the germinal centre

Productive immune responses to T-cell-dependent antigens ultimately generate two long-lived compartments: memory B cells and bone marrow-resident plasma cells, which both arise from within germinal centres. The ability of a B-cell clone to populate these effector compartments requires its descendents to outcompete those of other clones participating in the response. Selection occurs at several stages of the response and the criteria differ at these different stages. While affinity predominates as the key, underlying driving force of selection, there is a distinction made at the point at which germinal centre cells initiate entry into the plasma cell and memory B-cell compartments. Becoming a plasma cell requires high affinity and cannot be subverted by blocking cell death, while becoming a memory B cell is dependent on survival alone. While such survival is typically mediated by affinity within the GC, the distinction has important mechanistic implications.     

Mechanism of BLyS action in B cell immunity.

The B lymphocyte stimulator (BLyS), also known as BAFF, THANK, TALL-1 and zTNF4, is the most recent addition to the tumor necrosis factor family (TNF) ligands and has a unique role in B cell immunity. Its requirement for the humoral immune response is evident in mice lacking BlyS, which exhibit profound deficiencies in peripheral B cell development and maturation. It regulates the antibody response, as shown in mice overexpressing BLyS, which develop autoimmune manifestations resulting from peripheral B cell expansion and differentiation. Attenuation of apoptosis appears to underlie BLyS action in B cells. However, elucidation of the mechanism of BLyS has proven to be more challenging, because BLyS binds three different TNF receptors (TACI/BCMA/BAFF-R) and shares overlapping functions with a related TNF ligand, APRIL. The unique role of BLyS in B cell development and differentiation and the pathogenesis of autoimmune diseases, systemic lupus erythematosus (SLE) in particular, makes the study of BLyS and its downstream targets attractive in the development of novel therapies.     

Tumor necrosis factor (TNF) receptor superfamily member TACI is a high affinity receptor for TNF family members APRIL and BLyS

An expression cloning approach was employed to identify the receptor for B-lymphocyte stimulator (BLyS) and identified the tumor necrosis factor receptor superfamily member TACI as a BLyS-binding protein. Expression of TACI in HEK293T cells confers on the cells the ability to bind BLyS with subnanomolar affinity. Furthermore, a TACI-Fc fusion protein recognizes both the cleaved, soluble form of BLyS as well as the membrane BLyS present on the cell surface of a recombinant cell line. TACI mRNA is found predominantly in B-cells and correlates with BLyS binding in a panel of B-cell lines. We also demonstrate that TACI interacts with nanomolar affinity with the BLyS-related tumor necrosis factor homologue APRIL for which no clear in vivo role has been described. BLyS and APRIL are capable of signaling through TACI to mediate NF-kappaB responses in HEK293 cells. We conclude that TACI is a receptor for BLyS and APRIL and discuss the implications for B-cell biology.     

Maturation of the immune response in germinal centers.

Germinal centers develop in peripheral lymphatic tissue during the primary immune response and may play a crucial role in affinity maturation. We have compared the diversification of the antigen-specific repertoire of B cells, both from within and from outside the germinal centers, during the murine response to 2-phenyloxazolone (phOx). By sequencing V kappa Ox1 L-chains characteristic of phOx-specific antibodies, we show that somatic mutations accumulate in germinal center B cells and that a mutation conferring high affinity binding is found with increasing frequency. An analysis of V/D/J rearrangements suggests that this mutation occurred independently in many B cells, which were then preferentially expanded. We conclude that, although the hypermutation mechanism may be activated before germinal centers develop, affinity maturation by hypermutation and selection takes place in the germinal centers.     

Antigen-driven selection in germinal centers as reflected by the shape characteristics of immunoglobulin gene lineage trees: a large-scale simulation study

During the immune response, the generation of memory B lymphocytes in germinal centers involves affinity maturation of the cells’ antigen receptors, based on somatic hypermutation of receptor genes and antigen-driven selection of the resulting mutants. Affinity maturation is vital for immune protection, and is the basis of humoral immune learning and memory. Lineage trees of somatically hypermutated immunoglobulin genes often serve to qualitatively illustrate claims concerning the dynamics of affinity maturation in germinal centers. Here, we derive the quantitative relationships between parameters characterizing affinity maturation dynamics (proliferation, differentiation and mutation rates, initial affinity of the Ig to the antigen, and selection thresholds) and the mathematical properties of lineage trees, using a computer simulation which combines mathematical models for all mature B cell populations, stochastic models of hypermutation and selection, lineage tree generation and measurement of graphical tree characteristics. We identified seven key lineage tree properties, and found correlations of these with initial clone affinity and with the selection threshold. These two parameters were found to be the main factors affecting lineage tree shapes in both primary and secondary response trees. The results also confirm that recycling from centrocytes back to centroblasts is highly likely.     

Cutting edge: B cell receptor signals regulate BLyS receptor levels in mature B cells and their immediate progenitors

This study examines how B lymphocyte stimulator (BLyS) receptor expression and responsiveness are influenced by B cell receptor (BcR) signaling. Our results show that resting and BcR-stimulated B cells are dependent on BLyS for survival and that B cells remain BLyS responsive during BcR-induced activation. Further, BcR ligation up-regulates expression of the BLySR B cell maturation defect/BLySR3 (Bcmd/BR3), but not other known BLySRs. Finally, the coupling of BcR signaling with Bcmd/BR3 expression is limited to late transitional and mature B cells. Together, these findings establish the coupling of BcR signaling with Bcmd/BR3 expression as a fundamental aspect of follicular B cell selection, survival, and activation.     

Optimality of Mutation and Selection in Germinal Centers

The population dynamics theory of B cells in a typical germinal center could play an important role in revealing how affinity maturation is achieved. However, the existing models encountered some conflicts with experiments. To resolve these conflicts, we present a coarse-grained model to calculate the B cell population development in affinity maturation, which allows a comprehensive analysis of its parameter space to look for optimal values of mutation rate, selection strength, and initial antibody-antigen binding level that maximize the affinity improvement. With these optimized parameters, the model is compatible with the experimental observations such as the ∼100-fold affinity improvements, the number of mutations, the hypermutation rate, and the “all or none” phenomenon. Moreover, we study the reasons behind the optimal parameters. The optimal mutation rate, in agreement with the hypermutation rate in vivo, results from a tradeoff between accumulating enough beneficial mutations and avoiding too many deleterious or lethal mutations. The optimal selection strength evolves as a balance between the need for affinity improvement and the requirement to pass the population bottleneck. These findings point to the conclusion that germinal centers have been optimized by evolution to generate strong affinity antibodies effectively and rapidly. In addition, we study the enhancement of affinity improvement due to B cell migration between germinal centers. These results could enhance our understanding of the functions of germinal centers.     

Epstein-Barr virus and the B cell: a secret romance

Infection by the Epstein-Barr virus (EBV) in immunocompetent individuals seems mainly confined to antigen-experienced memory B cells. However, a recent report shows that EBV(+) post-transplant lymphoproliferative disease might arise not only from memory B cells but also from nai;ve and germinal center (GC) B cells. Intriguingly, some of the EBV-positive B-cell clones seem to carry non-functional Ig-V-region genes as a result of deleterious somatic mutations acquired during the GC reaction. Given that such GC B cells are destined to die by apoptosis in the absence of EBV, these findings suggest that transformation by EBV might bypass negative selection of B cells within GCs.     

TLR stimulation modifies BLyS receptor expression in follicular and marginal zone B cells

Through their differential interactions with B lymphocyte stimulator (BLyS) and a proliferation-inducing ligand (APRIL), the three BLyS family receptors play central roles in B cell survival and differentiation. Recent evidence indicates BLyS receptor levels shift following BCR ligation, suggesting that activation cues can alter overall BLyS receptor profiles and thus ligand sensitivity. In this study, we show that TLR stimuli also alter BLyS receptor expression, but in contrast to BCR ligation, TLR9 and TLR4 signals, preferentially increase transmembrane activator calcium modulator and cyclophilin ligand interactor (TACI) expression. Although both of these TLRs act through MyD88-dependent mechanisms to increase TACI expression, they differ in terms of their downstream mediators and the B cell subset affected. Surprisingly, only TLR4 relies on c-Rel and p50 to augment TACI expression, whereas TLR9 does not. Furthermore, although all follicular and marginal zone B cells up-regulate TACI in response to TLR9 stimulation, only marginal zone B cells and a subset of follicular B cells respond to TLR4. Finally, we find that both BLyS and APRIL enhance viability among quiescent and BCR-stimulated B cells. However, although BLyS enhances viability among TLR stimulated B cells, APRIL does not, suggesting that TACI but not BLyS receptor 3 may share survival promoting pathways with TLRs.     

Construction and function of two Cys146-mutants with high activity, derived from recombinant human soluble B lymphocyte stimulator

B lymphocyte stimulator (BLyS) is a novel member of tumor necrosis factor (TNF) ligand family that is important in B cell maturation and survival. Previous studies were almost related to the function or mechanism of its wild type. Here, we constructed two site-directed mutants of the recombinant human soluble BLyS, the BY-A and BY-V, and found that BY-V ranked the highest whenever in the process of promoting proliferation of B lymphocytes in vitro or stimulating total serum IgG and IgM secretion in vivo. Besides, assays for the biological responses of human leukemic cell lines to BLyS, BY-A and BY-V demonstrated that they could suppress the proliferation of Raji cells but promote the growth of THP-1. The discovery of BY-V with high activity will help come to a conclusion that the mutation of Cys146 to Val146 might improve the biological activity of BLyS.     

Cellular competition independent of BAFF/B lymphocyte stimulator results in low frequency of an autoreactive clonotype in mature polyclonal B cell compartments

The peripheral B cell prosurvival cytokine BAFF/B lymphocyte stimulator (BLyS) has been proposed to participate in the regulation of immunological tolerance. Selective elimination or reconstitution of B cells expressing transgene-encoded, autoreactive BCRs upon systemic BLyS depletion or supplementation, respectively, was observed in two separate studies. Such findings led to a model positing a higher dependency of autoreactive B cells on BLyS. We tested this model by exploiting two targeted IgH transgenic mice (H chain knock-in [HKI]) that produce large numbers of follicular (FO) B cells that are either weakly or strongly autoreactive with nuclear autoantigens. Even though HKI B cells do not exhibit classical features of anergy, we found that mature, naive, autoreactive HKI B cells are outcompeted for representation in the periphery by a polyclonal B cell population. However, this is not due to a higher dependency of HKI B cells on BLyS for survival. Additionally, excess BLyS does not rescue HKI B cells from selective elimination. These findings suggest that some autoreactive FO B cells can fully develop while in competition with non-autoreactive cells for BLyS, but remain at a competitive disadvantage for other trophic factors that regulate peripheral stability. As such, our data indicate the existence of peripheral tolerance mechanisms that regulate the frequency of autoreactive FO B cells independent of the BLyS pathway.