B cell receptor basal signaling regulates antigen-induced Ig light chain rearrangements

BCR editing in the bone marrow contributes to B cell tolerance by orchestrating secondary Ig rearrangements in self-reactive B cells. We have recently shown that loss of the BCR or a pharmacologic blockade of BCR proximal signaling pathways results in a global "back-differentiation" response in which immature B cells down-regulate genes important for the mature B cell program and up-regulate genes characteristic of earlier stages of B cell development. These observations led us to test the hypothesis that self-Ag-induced down-regulation of the BCR, and not self-Ag-induced positive signals, lead to Rag induction and hence receptor editing. Supporting this hypothesis, we found that immature B cells from xid (x-linked immunodeficiency) mice induce re-expression of a Rag2-GFP bacterial artificial chromosome reporter as well as wild-type immature B cells following Ag incubation. Incubation of immature B cells with self-Ag leads to a striking reversal in differentiation to the pro-/pre-B stage of development, consistent with the idea that back-differentiation results in the reinduction of genes required for L chain rearrangement and receptor editing. Importantly, Rag induction, the back-differentiation response to Ag, and editing in immature and pre-B cells are inhibited by a combination of phorbol ester and calcium ionophore, agents that bypass proximal signaling pathways and mimic BCR signaling. Thus, mimicking positive BCR signals actually inhibits receptor editing. These findings support a model whereby Ag-induced receptor editing is inhibited by BCR basal signaling on developing B cells; BCR down-regulation removes this basal signal, thereby initiating receptor editing.     

Ig light chain receptor editing in anergic B cells

Receptor editing in the bone marrow (BM) serves to modify the Ag receptor specificity of immature self-reactive B cells, while anergy functionally silences self-reactive clones. Here, we demonstrate that anergic B cells in hen egg lysozyme Ig (HEL-Ig)/soluble HEL double transgenic mice show evidence of having undergone receptor editing in vivo, as demonstrated by the presence of elevated levels of endogenous kappa light chain rearrangements in the BM and spleen. In an in vitro IL-7-driven BM culture system, HEL-Ig BM B cells grown in the presence of soluble HEL down-regulated surface IgM expression and also showed induction of new endogenous kappa light chain rearrangements. Using a panel of soluble protein ligands with reduced affinity for the HEL-Ig receptor, the editing response was shown to correlate in a dose-dependent fashion with the strength of signaling through the B cell receptor. The finding that the level of B cell receptor cross-linking sufficient to induce anergy in B cells is also capable of engaging the machinery required for receptor editing suggests an intimate relationship between these two mechanisms in maintaining B cell tolerance.     

Shark Ig light chain junctions are as diverse as in heavy chains

We have characterized a small family of four genes encoding one of the three nurse shark Ig L chain isotypes, called NS5. All NS5 cDNA sequences are encoded by three loci, of which two are organized as conventional clusters, each consisting of a V and J gene segment that can recombine and one C region exon; the third contains a germline-joined VJ in-frame and the fourth locus is a pseudogene. This is the second nurse shark L chain type where both germline-joined and split V-J organizations have been found. Since there are only two rearranging Ig loci, it was possible for the first time to examine junctional diversity in defined fish Ig genes, comparing productive vs nonproductive rearrangements. N region addition was found to be considerably more extensive in length and in frequency than any other vertebrate L chain so far reported and rivals that in H chain. We put forth the speculation that the unprecedented efficiency of N region addition (87-93% of NS5 sequences) may be a result not only of simultaneous H and L chain rearrangement in the shark but also of processing events that afford greater accessibility of the V or J gene coding ends to terminal deoxynucleotidyltransferase.     

Block in development at the pre-B-II to immature B cell stage in mice without Ig kappa and Ig lambda light chain

Silencing individual C (constant region) lambda genes in a kappa(-/-) background reduces mature B cell levels, and L chain-deficient (lambda(-/-)kappa(-/-)) mice attain a complete block in B cell development at the stage when L chain rearrangement, resulting in surface IgM expression, should be completed. L chain deficiency prevents B cell receptor association, and L chain function cannot be substituted (e.g., by surrogate L chain). Nevertheless, precursor cell levels, controlled by developmental progression and checkpoint apoptosis, are maintained, and B cell development in the bone marrow is fully retained up to the immature stage. L chain deficiency allows H chain retention in the cytoplasm, but prevents H chain release from the cell, and as a result secondary lymphoid organs are B cell depleted while T cell levels remain normal.     

Representation of heavy but not light chain Ig idiotypes on T cell receptors for alloantigens.

We have analyzed idiotypic determinants on B and T lymphocytes reactive against the same antigenic determinants by the use of different anti-idiotypic antibodies. Such antisera were produced in (Lewis X DA) F1 rats against Lewis anti-DA alloantibodies (= B cell product) and Lewis T lymphocyte receptors with the same specificity. We found that B lymphocytes bear unique idiotypic determinants which are not present on the corresponding T lymphocytes. T cell unique (not shared by B lymphocytes) idiotypes were so far not detected. T cells idiotypic determinants which are present on heavy but not light chains of the corresponding alloantibodies.     

The role of rearrangement at the second Ig heavy chain locus in maintaining B cell tolerance to DNA

In recently generated B6.56R anti-DNA autoantibody-transgenic mice, it was noted that a substantial fraction of the B cells that had avoided DNA reactivity had done so through the rearrangement and usage of the endogenous, nontargeted H chain (HC) allele. This suggested that rearrangement at the second HC locus might be an important mechanism through which self-reactive B cells might successfully revise their initial Ag specificity. To test the importance of this mechanism in B cell tolerance, we generated B6.56R/56R mice that possessed the 56R anti-DNA H chain transgene inserted into both HC loci. These transgenic homozygotes developed higher titers of anti-DNA Abs, with an expanded population of B220(low)MHC class II(low) B cells, enriched for CD21(low)CD23(low) preplasmablasts. The analysis of hybridomas from these mice revealed that the only avenue by which these B cells could avoid DNA reactivity was through the use of the editor L chains, V(k)20 or V(k)21. Hence, in addition to LC editing, rearrangement and usage of the second HC locus/allele constitutes an important safety valve for B cells the primary BCR of which confers DNA reactivity. In contrast to these tolerance mechanisms, editing the first rearranged HC locus (through HC replacement) and somatic mutations appear to be less frequently used to edit/revise self-reactive B cells.     

B cell clonal expansion and somatic hypermutation of Ig variable heavy chain genes in the synovial membrane of patients with osteoarthritis

Inflammatory mediators have been explored as possible factors in the initiation and/or progression of osteoarthritis (OA). This study shows that synovial infiltration by B lymphocytes is present in almost half of the knee OA cases. The degree of B lymphocyte infiltration is associated with more pronounced synovial inflammation and with the presence of plasma cells and lymphoid follicles in more severe cases. To examine whether these B cells are merely bystanders or could be involved in the pathogenesis of OA, we analyzed the Ig H chain variable region (V(H)) genes of B cells recovered from the synovial membrane of five OA patients with marked B cell infiltration. Sequence analysis of CDR3 regions of rearranged VDJ genes revealed clonal or oligoclonal B cell expansions in all cases. Expanded B cell clones in four of five OA patients showed clustered somatic mutations, occurring mainly in the CDRs and with a high replacement-to-silent ratio (>2.9), indicating that these cells are postgerminal center B cells that had been positively selected through their Ag receptor. These data demonstrate the presence in inflamed knee OA synovium of clonally expanded, Ag-driven B cells that may contribute to the development or progression of the disease.     

Regulation of human Ig lambda light chain gene expression by NF-kappa B.

The human Iglambda enhancer consists of three separated sequence elements that we identified previously by mapping DNase I-hypersensitive regions (HSS) downstream of the C region of the Iglambda L chain genes (HSS-1, HSS-2, and HSS-3). It has been shown by several laboratories that expression of the H chain genes as well as the kappa genes, but not the lambda genes, is dependent on constitutive NF-kappaB proteins present in the nucleus. In this study we show by band-shift experiments, in vivo footprinting, and transient transfection assays that all three hypersensitive sites of the human Iglambda enhancer contain functional NF-kappaB sites that act synergistically on expression. We further show that the chicken lambda enhancer also contains a functional NF-kappaB site but the mouse lambda enhancer contains a mutated, nonfunctional NF-kappaB site that is responsible for its low enhancer activity. It is possible that the inactivating mutation in the mouse Iglambda enhancer was compensated for by an expansion of the Igkappa L chain locus, followed by a contraction of the Iglambda locus in this species.     

Ig lambda and heavy chain gene usage in early untreated systemic lupus erythematosus suggests intensive B cell stimulation.

To determine the distribution of Vlambda and Jlambda as well as VH and JH gene usage in a patient with systemic lupus erythematosus (SLE), productive and nonproductive VJ and V(D)J rearrangements were amplified from individual peripheral CD19+ B cells and were analyzed. No differences in the Vlambda and Jlambda or the VH and JH gene usage in the nonproductive gene repertoire of this SLE patient were found compared with the distribution of genes found in normal adults, whereas marked skewing of both Vlambda and VH was noted among the productive rearrangements. The distribution of productive Vlambda rearrangements was skewed, with significantly greater representation of the Jlambda distal cluster C Vlambda genes and the Vlambda distal Jlambda7 element, consistent with the possibility that there was receptor editing of the Vlambda locus in this patient. Significant bias in VH gene usage was also noted with VH3 family members dominating the peripheral B cell repertoire of the SLE patient (83%) compared with that found in normal subjects (55%; p < 0.001). Notably, a clone of B cells employing the VH3-11 gene for the heavy chain and the Vlambda1G segment for the light chain was detected. These data are most consistent with the conclusion that extreme B cell overactivity drives the initial stages of SLE leading to remarkable changes in the peripheral V gene usage that may underlie on fail to prevent the emergence of autoimmunity.     

Frequency and characterization of phenotypic Ig heavy chain allelically included IgM-expressing B cells in mice

Ig H chain (IgH) allelic exclusion remains a puzzling topic. Here, we address the following question: Do phenotypic IgH allelically included cells exist in normal mice and, if so, at what frequency? Sorted cells from heterozygous mice were evaluated for the expression of both IgM allotypes by double intracytoplasmic stainings. Dual expressors were found at a frequency of 1 in 104 splenic B cells. These data were confirmed by direct sequencing of IgH-rearranged alleles obtained after single cell (or clone) PCR on dual expressors. Typically, these cells have one rearranged J558 VH whereas, in the other allele, a D-proximal VH gene is used. Interestingly, dual expressors have rearranged IgH alleles with similar CDR3 lengths. These results show that, in contrast to the kappa L chain and the TCR beta-chain, IgH allelic exclusion is the result of an extremely stringent mechanism. We discuss two non-mutually exclusive scenarios for the origin of IgH dual expressors: 1) IgH allelically included cells arise when the first allele to rearrange productively is unable to form a pre-BCR; dual expressors could be a subset of this population in which, upon conventional L chain rearrangement, both IgH are expressed at the surface; and 2) synchronous rearrangement of the IgH alleles.     

Similarities and differences between the light and heavy chain Ig variable region gene repertoires in chronic lymphocytic leukemia

Analyses of Ig V(H)DJ(H) rearrangements expressed by B-CLL cells have provided insights into the antigen receptor repertoire of B-CLL cells and the maturation stages of B-lymphocytes that give rise to this disease. However, less information is available about the L chain V gene segments utilized by B-CLL cells and to what extent their characteristics resemble those of the H chain. We analyzed the V(L) and J(L) gene segments of 206 B-CLL patients, paying particular attention to frequency of use and association, mutation status, and LCDR3 characteristics. Approximately 40% of B-CLL cases express V(L) genes that differ significantly from their germline counterparts. Certain genes were virtually always mutated and others virtually never. In addition, preferential pairing of specific V(L) and J(L) segments was found. These findings are reminiscent of the expressed VH repertoire in B-CLL. However unlike the V(H) repertoire, V(L) gene use was not significantly different than that of normal B-lymphocytes. In addition, Vkappa genes that lie more upstream on the germline locus were less frequently mutated than those at the 3' end of the locus; this was not the case for Vlambda genes and is not for V(H) genes. These similarities and differences between the IgH and IgL V gene repertoires expressed in B-CLL suggest some novel features while also reinforcing concepts derived from studies of the IgH repertoire.     

Clathrin heavy chain, light chain interactions

Purified pig brain clathrin can be reversibly dissociated and separated into heavy chain trimers and light chains in the presence of non-denaturing concentrations of the chaotrope thiocyanate. The isolated heavy chain trimers reassemble into regular polygonal cage structures in the absence of light chains. The light chain fraction can be further resolved into its two components L alpha and L beta which give different one-dimensional peptide maps. Radiolabelled light chains bind with high affinity (KD < 10(-10) M) to heavy chain trimers, to heavy chain cages and to a 110,000 mol. wt. tryptic fragment of the heavy chain. Both light chains compete with each other and with light chains from other sources for the same binding sites on heavy chains and c.d. spectroscopy shows that the two pig brain light chains possess very similar structures. We conclude that light chains from different sources, despite some heterogeneity, have a highly conserved, high affinity binding site on the heavy chain but are not essential for the formation of regular cage structures.     

Conventional and surrogate light chains differentially regulate Ig mu and Dmu heavy chain maturation and surface expression

Positive selection of precursor (pre-) B cells by Ig membrane mu H chains (mum HC) and counterselection mediated by the truncated HC Dmu depend on the ability of each HC to form a pre-B cell receptor (pre-BCR) signaling complex with the surrogate L chain (SLC) components lambda5 and Vpre-B. To better understand how pre-BCR signaling output is determined by its Ig components and the SLC, we investigated the regulation of pre-BCR surface expression and HC secretory maturation in a new nonlymphoid system. We took this approach as a means to distinguish B-lineage-specific effects from pre-BCR-intrinsic properties that may influence these aspects of pre-BCR homeostasis necessary for signaling. As in pre-B cells, the SLC in nonlymphoid cells supported only a limited degree of mum HC maturation and low pre-BCR surface expression levels compared with conventional LCs, indicating that this was due to an intrinsic property of the SLC. We identified the non-Ig region of lambda5 as harboring the restrictive activity responsible for this phenotype. This property of lambda5 was also evident with Dmu, but the overall SLC- and L chain-dependent requirements for Dmu maturation and surface expression were markedly different from those for mum. Surprisingly, Dmu was modified in an unusual manner that was only dependent on Vpre-B. These results establish a novel function of lambda5 in limiting surface pre-BCR levels and reveal biochemical properties of Ig molecules that may underlie the diverse consequences of pre-BCR signaling in vivo by different HCs.     

Burkitt lymphoma cell lines are prone to recombination in the switch region of the Ig mu heavy chain locus

Different recombinations have been found at the Ig heavy chain gene loci in a number of sublines of the Burkitt lymphoma (BL) cell line Namalwa, following prolonged in vitro culture. The Namalwa sublines examined are DNA fingerprint-identical and derived from a monoclonal source. Recombinant DNA clones were used to map the Ig heavy chain gene mutations to a region between the VDJ and C mu segment of the locus. This region is associated with Ig heavy chain class switching in normal B cells. Of 24 clones established from one subline, three were found to have additional VDJ-C mu region mutations, indicating a high frequency of mutation at this locus.     

DNA sequences 3' of the Ig H chain cluster rearrange in mouse B cell lines

A mouse myeloma cell line MPC11 (IgG2b, kappa) and variants derived from it have been used to study DNA rearrangements that occur at the Ig H chain locus. One variant, F5.5, has acquired both VH gene and C epsilon gene rearrangements. Through genomic Southern blot analysis initially directed to mapping the C epsilon gene rearrangement, we observed that the VH region rearrangement was linked, through an inversion event, to sequences that originate 3' of the CH cluster, i.e., 3' of the C alpha gene. Subsequent studies have shown that DNA rearrangements within the region 3' of the C alpha gene are detected in several other mouse myeloma and hybridoma cell lines and are not associated with the expression of specific isotypes.     

Organ-specific (localized) synthesis of Ig light chain amyloid

Ig amyloidosis is usually a systemic disease with multisystem involvement. However, in a significant number of cases amyloid deposition is limited to one specific organ. It has not been determined if the Ig light chain (LC) amyloid precursor protein in localized amyloidosis is synthesized by circulating plasma cells with targeting of the amyloid fibril-forming process to one specific organ, or whether the synthesis of Ig LC and fibril formation occurs entirely as a localized process. In the present study local synthesis of an amyloid fibril precursor LC was investigated. Amyloid fibrils were isolated from a ureter that was obstructed by extensive infiltration of the wall with amyloid. Amino acid sequence analysis of the isolated fibril subunit protein proved it to be derived from a lambdaII Ig LC. Plasma cells within the lesion stained positively with labeled anti-lambda Ab and by in situ hybridization using an oligonucleotide probe specific for lambda-LC mRNA. RT-PCR of mRNA extracted from the tumor and direct DNA sequencing gave the nucleotide sequence coding specifically for the lambdaII amyloid subunit protein, thus confirming local synthesis of the LC protein.     

Diverse endogenous light chains contribute to basement membrane reactivity in nonautoimmune mice transgenic for an anti-laminin Ig heavy chain

 Basement membrane proteins are targeted in a variety of pathologic autoimmune responses, yet little is known regarding the origins and regulation of this subset of pathogenic lymphocytes. To examine the generation and fate of B cells reactive with a matrix autoantigen, nonautoimmune C57BL/6 mice were rendered transgenic for a nephrotropic lupus anti-laminin immunoglobulin (Ig) H chain, termed LamH-Cμ. We previously reported recovery of two distinct phenotypes among LamH-Cμ-transgenic mice: progeny of founders M6 and M29 contained abundant transgene-expressing B cells but little anti-laminin Ig, whereas spontaneous autoreactivity was readily recovered from the M7 lineage that expressed minimal B-cell mIgM. To explore the spectrum of autoreactivity generated in vivo by different LamH-Cμ-endogenous L-chain combinations, we determined in vitro and in vivo antigen reactivity and L-chain V-region sequences of 17 LamH-Cμ-transgenic anti-laminin Igs. The results reveal a heterogeneous population of anti-laminin Igs with different fine specificities encoded by diverse endogenous L chains, encompassing nine different Vk gene families, 11 Vk genes, and three Jk genes. Many of the L chains are identical to known or putative unmutated germline Vk genes used to encode Igs reactive with self and foreign antigens in nonautoimmune and genetically autoimmune-prone mouse strains. These observations confirm that the LamH-Cμ H chain plays a dominant role in determining anti-laminin reactivity, and indicate that nonautoimmune B6 mice are fully capable of generating a diverse pool of basement-membrane-reactive B cells using unmutated Ig genes. When interpreted in the context of the divergent M6/M29 and M7 transgenic mouse phenotypes, our findings further suggest that these matrix-reactive lymphocytes are not spontaneously activated in vivo under normal circumstances. Received: 1 July 1999 / Revised: 28 July 1999     

Slow myosin heavy chain expression in the absence of muscle activity

Innervation has been generally accepted to be a major factor involved in both triggering and maintaining the expression of slow myosin heavy chain (MHC-1) in skeletal muscle. However, previous findings from our laboratory have suggested that, in the mouse, this is not always the case (30). Based on these results, we hypothesized that neurotomy would not markedly reduced the expression of MHC-1 protein in the mouse soleus muscles. In addition, other cellular, biochemical, and functional parameters were also studied in these denervated soleus muscles to complete our study. Our results show that denervation reduced neither the relative amount of MHC-1 protein, nor the percentage of muscle fibers expressing MHC-1 protein (P > 0.05). The fact that MHC-1 protein did not respond to muscle inactivity was confirmed in three different mouse strains (129/SV, C57BL/6, and CD1). In contrast, all of the other histological, biochemical, and functional muscle parameters were markedly altered by denervation. Cross-sectional area (CSA) of muscle fibers, maximal tetanic isometric force, maximal velocity of shortening, maximal power, and citrate synthase activity were all reduced in denervated muscles compared with innervated muscles (P < 0.05). Contraction and one-half relaxation times of the twitch were also increased by denervation (P < 0.05). Addition of tenotomy to denervation had no further effect on the relative expression of MHC-1 protein (P > 0.05), despite a greater reduction in CSA and citrate synthase activity (P < 0.05). In conclusion, a deficit in neural input leads to marked atrophy and reduction in performance in mouse soleus muscles. However, the maintenance of the relative expression of slow MHC protein is independent of neuromuscular activity in mice.