B cell ligand discrimination through a spreading and contraction response.

B cells recognize foreign antigens by virtue of cell surface immunoglobulin receptors and are most effectively activated by membrane-bound ligands. Here, we show that in the early stages of this process, B cells exhibit a two-phase response in which they first spread over the antigen-bearing membrane and then contract, thereby collecting bound antigen into a central aggregate. The extent of this response, which is both signaling- and actin-dependent, determines the quantity of antigen accumulated and hence the degree of B cell activation. Brownian dynamic simulations reproduce essential features of the antigen collection process and suggest a possible basis for affinity discrimination. We propose that dynamic spreading is an important step of the immune response.

B cells acquire antigen from target cells after synapse formation.

Soluble antigen binds to the B-cell antigen receptor and is internalized for subsequent processing and the presentation of antigen-derived peptides to T cells. Many antigens are not soluble, however, but are integral components of membrane; furthermore, soluble antigens will usually be encountered in vivo in a membrane-anchored form, tethered by Fc or complement receptors. Here we show that B-cell interaction with antigens that are immobilized on the surface of a target cell leads to the formation of a synapse and the acquisition, even, of membrane-integral antigens from the target. B-cell antigen receptor accumulates at the synapse, segregated from the CD45 co-receptor which is excluded from the synapse, and there is a corresponding polarization of cytoplasmic effectors in the B cell. B-cell antigen receptor mediates the gathering of antigen into the synapse and its subsequent acquisition, thereby potentiating antigen processing and presentation to T cells with high efficacy. Synapse formation and antigen acquisition will probably enhance the activation of B cells at low antigen concentration, allow context-dependent antigen recognition and enhance the linking of B- and T-cell epitopes.

Memory in the B-cell compartment: antibody affinity maturation.

In the humoral arm of the immune system, the memory response is not only more quickly elicited and of greater magnitude than the primary response, but it is also different in quality. In the recall response to antigen, the antibodies produced are of higher affinity and of different isotype (typically immunoglobulin G rather than immunoglobulin M). This maturation rests on the antigen dependence of B-cell maturation and is effected by programmed genetic modifications of the immunoglobulin gene loci. Here we consider how the B-cell response to antigen depends on the affinity of the antigen receptor interaction. We also compare and draw parallels between the two processes, which underpin the generation of secondary-response antibodies: V gene somatic hypermutation and immunoglobulin heavy-chain class switching.

Diversification and selection mechanisms for the production of protein repertoires: lessons from the immune system.

The physiological mechanism for producing antigen-specific antibodies is based on a two-phase neo-Darwinian process: the first phase consists of diversity generation (formation of the repertoire), and the second phase is antigen-mediated selection. In this article, we consider how the natural immunoglobulin gene-diversification processes can be exploited both in vivo and in vitro in order to allow the generation of novel antibody (and heterologous protein) repertoires.

B cells extract and present immobilized antigen: implications for affinity discrimination.

Binding of antigen to B-cell antigen receptor (BCR) leads to antigen internalization and presentation to T cells, a critical process in the initiation of the humoral immune response. However, antigen internalization has been demonstrated for soluble antigen, in vivo antigen is often encountered in insoluble form or tethered to a cell surface. Here, we show that not only can B cells internalize and present large particulate antigen (requiring a signalling-competent BCR to drive antigen uptake), but they can also extract antigen that is tethered tightly to a non-internalizable surface. The form in which the antigen is displayed affects the B cell's ability to discriminate antigen-BCR affinity. Thus, arraying an antigen on a particle or surface allows efficient presentation of low affinity antigens. However, the presentation efficiency of antigen arrayed on an internalizable particle plateaus at low affinity values. In contrast, extraction and presentation of antigen from a non-internalizable surface depends on antigen-BCR affinity over a wide affinity range. The results have implications for understanding both the initiation and affinity maturation of the immune response.

Deficiency in CD22, a B cell-specific inhibitory receptor, is sufficient to predispose to development of high affinity autoantibodies.

CD22 is a B cell-specific transmembrane glycoprotein that acts to dampen signals generated through the B cell antigen receptor (BCR): B cells from CD22-deficient mice give increased Ca2+ fluxes on BCR ligation. Here we show that this B cell hyperresponsiveness correlates with the development of autoantibodies. After the age of eight months, CD22-deficient mice developed high titers of serum IgG directed against double-stranded DNA; these antibodies were of multiclonal origin, somatically mutated, and high affinity. Increased titers of antibodies to cardiolipin and myeloperoxidase were also noted. The results demonstrate that a single gene defect exclusive to B lymphocytes is, without additional contrivance, sufficient to trigger autoantibody development in a large proportion of aging animals. Thus, CD22 might have evolved specifically to regulate B cell triggering thresholds for the avoidance of autoimmunity.

Affinity dependence of the B cell response to antigen: a threshold, a ceiling, and the importance of off-rate.

Initiation and affinity maturation of the humoral immune response is driven by antigen interaction with BCR. To study how signaling and antigen presentation through BCR depend on antigen/BCR affinity, lysozyme-specific B cell transfectants were challenged with mutated lysozymes differing in their binding kinetics. For detectable triggering, the antigen/BCR complex needed a Ka > 10(6) M(-1) (dissociation half-life > approximately 1 s). Mutated lysozymes whose binding was below this threshold could nevertheless be presented if complexed with soluble antibody. Above the threshold, the concentration of antigen required to trigger a response decreased as the affinity (particularly dissociation half-life) increased. However, a plateau was reached at Kas > approximately 10(10) M(-1) (dissociation half-life > 0.5 hr), supporting the idea of a ceiling to affinity maturation.

A temperature-sensitive DNA adenine methyltransferase mutant of Salmonella typhimurium.

A temperature-sensitive mutant of Salmonella typhimurium was isolated earlier after transposon mutagenesis with Tn10d Tet. The mutant D220 grows well at 28 degreesC but has a lower growth rate and forms filaments at 37 degreesC. Transposon-flanking fragments of mutant D220 DNA were cloned and sequenced. The transposon was inserted in the dam gene between positions 803 and 804 (assigned allele number: dam-231 : : Tn10d Tet) and resulted in a predicted ten-amino-acid-shorter Dam protein. The insertion created a stop codon that led to a truncated Dam protein with a temperature-sensitive phenotype. The insertion dam-231 : : Tn10d Tet resulted in a dam "leaky" phenotype since methylated and unmethylated adenines in GATC sequences were present. In addition, the dam-231 : : Tn10d Tet insertion rendered dam mutants temperature-sensitive for growth depending upon the genetic background of the S. typhimurium strain. The wild-type dam gene of S. typhimurium exhibited 82% identity with the Escherichia coli dam gene.

Multiple transcripts of the murine immunoglobulin epsilon membrane locus are generated by alternative splicing and differential usage of two polyadenylation sites.

The human C epsilon gene produces a number of alternatively spliced heavy chain transcripts of which some encode functional IgE isoforms. We now show that differentially processed epsilon mRNA variants also exist in the mouse and are generated by differential polyadenylation and alternative splicing of primary epsilon chain transcripts. The two poly(A) sites of the mouse membrane transcripts were identified in the present study by RACE-PCR analysis. The first poly(A) site is located 743 nt downstream from the beginning of the second membrane exon (M2) and contains the same non-consensus AGTAAA signal sequence as the single poly(A) site of the human membrane transcripts. The second poly(A) site is located almost 500nt further downstream and is characterized by an AAGAAA hexamer. This poly(A) site contains a (G+T) rich element downstream to the site of cleavage and polyadenylation and is preferentially utilized by the membrane epsilon transcripts. Additional diversity of epsilon transcripts is generated by alternative splicing between the last constant region exon (CH4) and the two membrane exons (M1 and M2). The alternatively spliced transcripts include two variants that skip the first membrane exon and encode epsilon heavy chains that lack the transmembrane domain. The third variant is generated by splicing to an internal site in M2 and codes for a membrane isoform that is 10 amino acids shorter in the cytoplasmic domain than the classical membrane IgE. Although little amino-acid sequence homology exists between the murine epsilon chain isoforms and their human counterparts, the pattern of splicing is rather conserved between the two species.

The two membrane isoforms of human IgE assemble into functionally distinct B cell antigen receptors.

The human C epsilon gene expresses two membrane IgE heavy chain mRNAs which differ in the sequence that encodes their extracellular membrane-proximal domain. In the long IgE isoform (mLIgE), this domain contains a stretch of 52 amino acids which are absent in the short variant (mSIgE). We have now generated B cell transfectoma cell lines that express these two isoforms and show that both types of mIgE form functional B cell antigen receptors (BCR). Both receptors associate with the Ig-alpha/Ig-beta heterodimer, as well as with protein kinases that are capable of phosphorylating this complex. Upon their cross-linking, both receptors can activate protein tyrosine kinases that phosphorylate the same substrate proteins. Both IgE receptors also associate with two novel proteins that do not bind to mIgM. Apart from these similarities, the two IgE-BCRs show several differences of which some are analogous to the differences between the IgM- and IgD-BCRs. First, the mSIgE is transported to the cell surface at a higher rate than the mLIgE. Second, the two IgE-BCRs associate with differently glycosylated Ig-alpha proteins, the mLIgE associates with the completely glycosylated form, whereas the mSIgE associates with an Ig-alpha glycoform that is partially sensitive to endoglycosidase H. Third, the kinetics of protein tyrosine phosphorylation induced by receptor cross-linking is significantly different for the two IgE-BCRs. Finally, cross-linking of the mSIgE-BCR leads to growth inhibition of the B cell transfectoma, whereas signaling through the mLIgE-BCR does not affect the cellular proliferation. These data show that the two human membrane IgE isoforms assemble into functionally distinct antigen receptors which can induce different cellular responses.

IgM-producing chronic lymphocytic leukemia cells undergo immunoglobulin isotype-switching without acquiring somatic mutations.

The malignant B cells in chronic lymphocytic leukemia (CLL) typically express low-density membrane IgM or IgM/IgD. In vitro experiments have shown that the CLL cells can be induced to differentiate into cells that secrete immunoglobulin (Ig) and can occasionally undergo heavy (H) chain class switching. We now show that the CLL cells also undergo isotype-switching in vivo, since gamma and/or alpha H chain transcripts with identical FW3/CDR3/FW4 regions as the mu CLL transcripts were detected in all of the 13 investigated patients with IgM+ CLL. In most cases switching had occurred to alpha1 and gamma3, but CLL transcripts corresponding to the other gamma chain isotypes were also detected. In one case both the productively and nonproductively rearranged allele were found to undergo H chain class switching. CLL gamma transcripts were also present in surface IgG+ sorted B cells, demonstrating that a small subset of the CLL cells express membrane IgG. In addition, transcripts encoding secretary gamma2 and gamma3 H chains were detected in two cases, which suggests that some serum IgG could be produced by the leukemic clone. Analysis of sorted PBL showed that isotype-switching occurs in CLL cells that express the CD5 antigen. Finally, nucleotide sequence analysis showed that the mu, alpha, and gamma CLL transcripts are identical, demonstrating that the CLL cells do not accumulate somatic mutations in their variable region genes after the H chain class switching. These data provide in vivo evidence that isotype-switching is a frequent phenomenon in CLL, and indicate that a subset of the CLL lymphocytes progress to later stages of B cell differentiation.

Restricted immunoglobulin VH region repertoire in chronic lymphocytic leukemia patients with autoimmune hemolytic anemia.

Between 10% and 25% of chronic lymphocytic leukemia (CLL) patients have episodes of autoimmune hemolytic anemia (AIHA) during the course of their disease. The anti-erythrocyte autoantibodies in most cases are polyclonal and express a different heavy chain isotype than the malignant clone, indicating that they are secreted by normal autoreactive B lymphocytes. To further investigate the pathogenesis of the AIHA in CLL, we analyzed the lg heavy (H) chain variable region genes expressed by leukemic cells from CLL patients with and without AIHA. Two VH genes were preferentially expressed by the leukemic cells in the CLL cases with AIHA and were present in 9 of the 12 investigated cases. The 51p1/DP-10 gene was expressed in 5 of these cases and was absent in the control group of 12 consecutive CLL cases without AIHA, whereas the DP-50 gene was present in 4 CLL-AIHA cases and only once in the control CLL group. A strikingly similar H-chain CDR3 region that contained a single reading frame of the DXP4 DH gene segment, and N-encoded proline at the DH/JH boundary, and a tyrosine-rich region encoded by the JH6 gene segment was observed in four CLL-AIHA cases. The preferential expression of two VH gene segments and a particular CDR3 region by the leukemic cells of patients with AIHA suggests that the antibodies produced by the CLL cells are directly involved in the pathogenesis of the hemolytic anemia.

Characterization of a second secreted IgE isoform and identification of an asymmetric pathway of IgE assembly.

A number of alternatively spliced epsilon transcripts have been detected in IgE-producing B cells, in addition to the mRNAs encoding the classical membrane and secreted IgE heavy (H) chains. In a recent study, we examined the protein products of three of these alternatively spliced isoforms and found that they are intracellularly retained and degraded because of their inability to assemble into complete IgE molecules. We have now similarly examined a more recently described epsilon mRNA species that is generated by splicing between a donor splice site immediately upstream of the stop codon in the H-chain constant region exon 4 (CH4) and an acceptor site located in the 3' part of the second membrane exon. We show that this isoform is efficiently secreted by both plasma cells and B lymphocytes and therefore represents a second secreted IgE isoform (epsilon S2). The epsilon S2 H chain is only six amino acids longer than the classical secreted Ig H chain (epsilon S1) and contains a C-terminal cysteine, which is a characteristic sequence feature of mu and alpha H chains. However, unlike IgM and IgA, the epsilon S2 C-terminal cysteine (Cys-554) does not induce polymerization of H2L2 molecules (where L is light chain), but rather creates a disulfide bond between the two H chains that increases the rate of association into covalently bound H2L2 monomers. This C-terminal cysteine also does not function as an intracellular retention element because the epsilon S2 isoform was secreted in amounts equal to that of the epsilon S1, both in B lymphocytes and in plasma cells. The epsilon S2 H chains secreted by B lymphocytes differed from the epsilon S1 H chains in the extent of glycosylation. Interestingly, a difference in glycosylation between B-lymphocytes and plasma cells was also noted for both isoforms. The presence of the Cys-554 also allowed the identification of a distinctive asymmetric pathway of IgE assembly, common to both types of epsilon H chains.

Characterization of the human immunoglobulin epsilon mRNAs and their polyadenylation sites.

Several IgE heavy (H) chain transcripts are produced by alternative splicing between constant region (CH3 and CH4) and membrane (M1 and M2) exons and by differential cleavage-polyadenylation at poly(A) sites downstream of the CH4 and M2 exons. We have now characterized the poly(A) signal of the epsilon transcripts that contain membrane exon sequences (epsilon CH4-M1'-M2, epsilon CH4-M1-M2, epsilon CH4-M2' and epsilon CH4-M2") and have determined the complete sequence of the M2 exon and 1.4 kb of downstream genomic DNA. The membrane locus poly(A) site was identified by RACE-PCR analysis of epsilon transcripts obtained from IgE-producing myeloma cells and normal peripheral blood lymphocytes (PBL). All membrane exon transcripts were found to be polyadenylated following a CA dinucleotide located 1046 nt from the beginning of the M2 exon. An AGTAAA hexamer, located 13 nt upstream from the site of cleavage and polyadenylation, was the only poly(A) signal sequence present in the 1.4 kb of genomic DNA downstream of the M2 exon. A (G+T)-rich region, which is also conserved in most poly(A) signals, was present 50 nt downstream of the AGTAAA hexamer. Northern blot analysis confirmed that this poly(A) site is used by the membrane exon epsilon mRNAs expressed by the U266 myeloma. The four membrane exon transcripts were detected in different relative amounts in PBL and IgE-producing myeloma cells, which could reflect different epsilon mRNA splicing patterns during B-cell differentiation.

Characterization and expression of alternatively spliced IgE heavy chain transcripts produced by peripheral blood lymphocytes.

We have investigated the IgE heavy chain isoforms produced in vivo by analyzing the epsilon mRNA species present in unstimulated PBL and expressing them individually in a myeloma cell line. Seven epsilon mRNA species were identified by using reverse transcription-PCR, cloning, and sequencing analysis. These species included the classical secreted (epsilon CH4-S) and membrane-bound (epsilon CH4-M1'-M2) IgE and five alternatively spliced epsilon transcripts. At the protein level, the five alternatively spliced epsilon transcripts (epsilon CH4*, epsilon CH4-M2', epsilon CH4'-1, epsilon CH4'-1-M2, and epsilon CH3-13-CH4) corresponded to four epsilon heavy chain isoforms, in which various parts of the CH4 domain were replaced by new stretches of amino acids at the carboxyl termini. The same epsilon mRNA species also were present in the IgE producing myeloma cell line U266. However, except for the classical membrane and secreted IgE, the corresponding proteins could not be identified. To further characterize the epsilon CH4-S, epsilon CH4*, epsilon CH4-M2', epsilon CH4'-1, and epsilon CH4-M1'-M2 species, we expressed them as chimeric mouse/human anti-4-hydroxy-5-iodo-3-nitrophenacetyl Abs in a mouse myeloma cell line. Only the classical secreted and membrane isoforms were found to be secreted or expressed on the cell surface, respectively, and the other forms were retained within the cells and degraded. These data suggest that some of the epsilon mRNA isoforms produced by PBL are aberrantly spliced mRNAs, the protein products of which are eliminated by post-translational events.

Molecular analysis of IgE H-chain transcripts expressed in vivo by peripheral blood lymphocytes from normal and atopic individuals.

The low levels of IgE produced by PBMC from normal individuals has so far prevented an analysis of their IgE H chain repertoire. Using a nested polymerase chain reaction approach, we were able to detect epsilon transcripts in all normal and allergic individuals we investigated. We further cloned epsilon CDR3/FW4 regions from two normal and two atopic individuals with low serum IgE levels. Sequence analysis of 104 clones identified 26 different epsilon CDR3/FW4 regions and an additional number of clonally related transcripts in the two atopic individuals. Preferential usage of DH genes from the DXP family (33%) and of the JH4b gene (35%) were observed, similar to reported findings for the IgM-producing peripheral blood B cell subset. Using CDR3 specific oligonucleotides, we detected the CDR3/FW4 regions of a particular set of clonally related epsilon transcripts in mu and gamma 4 transcripts of the same individual. This finding demonstrates the in vivo production of IgE together with the two other Ig isotypes (IgM and IgG4) by the progeny of a common B cell precursor, and suggests a possible mechanism for regulating the allergic response. The clonally related epsilon transcripts were found to be only of the secreted form. We give also evidence that the IgE-producing B cells undergo somatic mutation because a number of identical mutations were observed in the FW4 regions of epsilon and mu clonally related transcripts. Some of these mutations were shared with other transcripts from the same and other individuals, supporting the existence of sequence-specific hot spots for the somatic hyper-mutation machinery in the JH gene segments.

A DNA topoisomerase I inhibitor blocks the differentiation of rat granulosa cells induced by follicle-stimulating hormone.

Follicle-stimulating hormone (FSH), acting through a cycle AMP-mediated mechanism, promotes differentiation of rat granulosa cells cultured in a defined medium. Camptothecin, a DNA topoisomerase I blocker, inhibited the increase in progesterone and oestradiol production stimulated by FSH. This effect was not due to non-specific inhibition of protein synthesis, as shown by measurement of [35S]methionine incorporation. A transient increase in DNA topoisomerase I activity was observed after 24 h of culture in the presence of FSH or dibutyryl cyclic AMP. Our results are consistent with a key role for DNA topoisomerase I in the modulation of gene expression by FSH in rat granulosa cells.