Differential surrogate light chain expression governs B-cell differentiation

Mutational Analysis of the VPREB1 Gene of Pre-BCR Complex in a Cohort of Sporadic Pediatric Patients With B-Cell Acute Lymphoblastic Leukemia

During bone marrow B-cell development, the pre-B-cell receptor is formed by the association of the immunoglobulin heavy chain with a surrogate light chain, which is encoded by the VPREB1, and λ5 genes. It is known that pre-BCR signaling signifies a critical checkpoint at the pre-B-cell stage. Thus, failure pre-BCR signaling is proposed as a critical factor for the development of B-cell acute lymphoblastic leukemia (B-ALL). B‑ALL is the most common pediatric cancer and is one of the leading causes of death in children. Until now, several molecular analyses were performed for genomic alterations in B-ALL, but for genomic analysis of the VPREB1 gene and its rare variations, limited studies have been conducted. In this study, using polymerase chain reaction and direct sequencing of 88 pediatric patients with B-ALL, we investigated the genomic region of the VPREB1 gene to find sequence variations of this gene. Our study presented ten homozygous and heterozygous point mutations and heterozygous nucleotide deletions, in the VPREB1 gene in 36 boys and 32 girls' patients. Our Bioinformatics assay results presented that these variations may alter the RNA folding, protein structure, and therefore probable effect on the protein function. These results propose that nucleotide changes probably contribute to B-ALL pathogenesis.

Contribution of secondary Igkappa rearrangement to primary immunoglobulin repertoire diversification

Abs reactive to DNA and DNA/histone complexes are a distinguished characteristic of primary immunoglobulin repertoires in autoimmune B6.MRL-Fas^lpr and MRL/MpJ-Fas^lpr mice. These mice are defective in Fas receptor, which is critical for the apoptosis of autoreactive B cells by an extrinsic pathway. In the present study, we explored the possibility that bone marrow small pre-B and immature B cells from adult B6.MRL-Fas^lpr mice and MRL/MpJ-Fas^lpr mice respectively, which contain autoreactive B-cell antigen receptors (BCR) and manifest autoimmune syndromes, exhibit enhanced receptor editing patterns. Indeed, FAS^lpr pre B and immature B cells were shown to possess more ongoing replacements of non-productive (nP) than productive (P) primary VκJκ rearrangements. Significantly, the P vs nP ratios of these replaced primary rearrangements were 1:2, thus indicating that κ light-chain production appears not to inhibit secondary rearrangements. In addition, we identified multiple atypical rearrangements, such as Vκ cRS (cryptic recombination signals) cleavages. These results suggest that the onset of light chain secondary rearrangements persists similarly as a non-selected mode and independent of BCR autoreactivity during certain developmental windows of bone marrow B cells in lupus-prone mice and control, and leads us to propose the function of secondary, de novo Igκ rearrangements to increase BCR diversity.

A novel mechanism for the autonomous termination of pre-B cell receptor expression via induction of lysosome-associated protein transmembrane 5

The expression of the pre-B cell receptor (BCR) is confined to the early stage of B cell development, and its dysregulation is associated with anomalies of B-lineage cells, including leukemogenesis. Previous studies suggested that the pre-BCR signal might trigger the autonomous termination of pre-BCR expression even before the silencing of pre-BCR gene expression to prevent sustained pre-BCR expression. However, the underlying mechanism remains ill defined. Here we demonstrate that the pre-BCR signal induces the expression of lysosome-associated protein transmembrane 5 (LAPTM5), which leads to the prompt downmodulation of the pre-BCR. While LAPTM5 induction had no significant impact on the internalization of cell surface pre-BCR, it elicited the translocation of a large pool of intracellular pre-BCR from the endoplasmic reticulum to the lysosomal compartment concomitantly with a drastic reduction of the level of intracellular pre-BCR proteins. This reduction was inhibited by lysosomal inhibitors, indicating the lysosomal degradation of the pre-BCR. Notably, the LAPTM5 deficiency in pre-B cells led to the augmented expression level of surface pre-BCR. Collectively, the pre-BCR induces the prompt downmodulation of its own expression through the induction of LAPTM5, which promotes the lysosomal transport and degradation of the intracellular pre-BCR pool and, hence, limits the supply of pre-BCR to the cell surface.

Ectopic B-cell clusters that infiltrate transplanted human kidneys are clonal

B cells and their immunoglobulin products participate in allograft rejection of transplanted human kidneys in which an interesting feature is the presence of a germinal center like B-cell clusters in the allograft. We report here that the immunoglobulin repertoires of these infiltrating B cells are highly restricted and the B cells within a cluster are clonal. Antibody libraries made from the infiltrating B cells of individual patients unexpectedly revealed that each patient utilizes a particular set of dominant germ line genes as well as dominant complementarity determining region 3. Comparison of kidney and peripheral blood from the same patient showed that the immunoglobulin genes from both compartments had dominant clones, but they differed. The lymphocytes that infiltrate the kidneys express the immunoglobulin gene somatic recombination machinery usually restricted to highly activated lymphocytes in germinal centers and lymphomas. An analogy can be made between the inescapable antigenic drive in chronic infection versus that in an allograft, both of which may lead to emergence of dominant B-cell clones and even lymphoid malignancy.

Interferon regulatory factors 4 and 8 induce the expression of Ikaros and Aiolos to down-regulate pre-B-cell receptor and promote cell-cycle withdrawal in pre-B-cell development

Pre-B lymphocytes consist of 2 distinct cell populations: large pre-B and small pre-B. The large pre-B cells are newly generated pre-B cells that express pre-B-cell receptor (pre-BCR) on the surface and are highly proliferative; small pre-B cells are derived from large pre-B cells that have down-regulated pre-BCR and withdrawn from cell cycle. The molecular events that mediate the transition from cycling pre-B to small, resting pre-B have not been fully elucidated. Here, we show that interferon regulatory factors 4 and 8 (IRF4,8) suppress surrogate light chain expression and down-regulate pre-BCR in pre-B cells. Our studies further reveal that IRF4,8 induce the expression of Ikaros and Aiolos in pre-B cells, and reconstitution of expression of either one is sufficient to suppress surrogate light chain expression and down-regulate pre-BCR in pre-B cells lacking IRF4,8. Interestingly, our results also indicate that pre-B cells undergo growth inhibition and cell-cycle arrest in the presence of IRF4,8. Moreover, we provide evidence that Ikaros and Aiolos are indispensable for the down-regulation of pre-BCR and the cell-cycle withdrawal mediated by IRF4,8. Thus, IRF4,8 orchestrate the transition from large pre-B to small pre-B cells by inducing the expression of Ikaros and Aiolos.

Essential role of phospholipase C gamma 2 in early B-cell development and Myc-mediated lymphomagenesis

Phospholipase Cgamma2 (PLCgamma2) is a critical signaling effector of the B-cell receptor (BCR). Here we show that PLCgamma2 deficiency impedes early B-cell development, resulting in an increase of B220+ CD43+ BP-1+ CD24hi pre-BCR+ large pre-B cells. PLCgamma2 deficiency impairs pre-BCR-mediated functions, leading to enhanced interleukin-7 (IL-7) signaling and elevated levels of RAGs in the selected large pre-B cells. Consequently, PLCgamma2 deficiency renders large pre-B cells susceptible to transformation, resulting in dramatic acceleration of Myc-induced lymphomagenesis. PLCgamma2(-/-) Emu-Myc transgenic mice mainly develop lymphomas of B220+ CD43+ BP-1+ CD24hi pre-BCR+ large pre-B-cell origin, which are uncommon in wild-type Emu-Myc transgenics. Furthermore, lymphomas from PLCgamma2(-/-) Emu-Myc transgenic mice exhibited a loss of p27Kip1 and often displayed alterations in Arf or p53. Thus, PLCgamma2 plays an important role in pre-BCR-mediated early B-cell development, and its deficiency leads to markedly increased pools of the most at-risk large pre-B cells, which display hyperresponsiveness to IL-7 and express high levels of RAGs, making them prone to secondary mutations and Myc-induced malignancy.

Assembly of the kappa preB receptor requires a V kappa-like protein encoded by a germline transcript

By confining germline transcription as a byproduct of the mechanisms inherent to genetic rearrangements, the translation of respective mRNAs and their biological relevance might have been overlooked. Here we report the identification, cloning, and biochemical characterization of a human Vkappa-like protein that is encoded by a germline transcript. This surrogate protein assembles with the immunoglobulin mu heavy chain at the surface of B cell progenitors and precursors to form a kappa-like antigen receptor. These findings support the notion that germline transcription is not futile and stress the flexibility in eukaryotic gene usage and expression. In addition, the present study confirms the co-existence of surrogate lambda and kappa receptors that are proposed to work in concert to promote B lymphocyte maturation.

Selective gene expression in multigene families from yeast to mammals

Exclusive gene expression, where only one member of a gene or gene cassette family is selected for expression, plays an important role in the establishment of cell identity in several biological systems. Here, we compare four such systems: mating-type switching in fission and budding yeast, where cells choose between expressing one of the two different mating-type cassettes, and immunoglobulin and odorant receptor gene expression in mammals, where the number of gene choices is substantially higher. The underlying mechanisms that establish this selective expression pattern in each system differ in almost every detail. In all four systems, once a successful gene activation event has taken place, a feedback mechanism affects the fate of the cell. In the mammalian systems, feedback is mediated by the expressed cell surface receptor to ensure monoallelic gene expression, whereas in the yeasts, the expressed gene cassette at the mating-type locus affects donor choice during the subsequent switching event.

Modeling first-hit functions of the t(12;21) TEL-AML1 translocation in mice

The t(12;21) translocation, which generates the TEL-AML1 (ETV6-RUNX1) fusion gene, is the most common structural chromosome change in childhood cancer and is exclusively associated with the common B cell precursor subset of acute lymphoblastic leukemia (ALL). Evidence suggests that the translocation usually occurs in utero during fetal hemopoiesis and most probably constitutes an initiating or first-hit mutation that is necessary but insufficient for the development of overt, clinical leukemia. The mechanism by which TEL-AML1 contributes to this early stage of leukemogenesis is unknown. To address this question we have analyzed hemopoiesis in mice syngeneically transplanted with TEL-AML1-transduced bone marrow stem cells. TEL-AML1 expression was associated with an accumulation/expansion of primitive c-kit-positive multipotent progenitors and a modest increase in myeloid colony-forming cells. TEL-AML1 expression was, however, permissive for myeloid differentiation. Analysis of B lymphopoiesis revealed an increase in early, pro-B cells but a differentiation deficit beyond that stage, resulting in reduced B cell production in the marrow. TEL-AML1-positive B cell progenitors exhibited reduced expression of the surrogate light-chain component lambda5 and the IL-7 receptor, both of which may contribute to impedance of differentiation in vivo and account for their reduced in vitro clonogenicity in IL-7. A selective differentiation deficit of B lineage progenitors (i) is consistent with the phenotype of TEL-AML1-associated leukemia in children and (ii) provides a potential mechanism for the protracted preleukemic state that often precedes ALL. These results provide mechanistic insight into the role of the t(12;21) translocation in the initiation of common B cell precursor ALL.

Human cord blood CD34+Pax-5+ B-cell progenitors: single-cell analyses of their gene expression profiles

Circulating CD34(+) cells are used in reparative medicine as a stem cell source, but they contain cells already committed to different lineages. Many think that B-cell progenitors (BCPs) are confined to bone marrow (BM) niches until they differentiate into B cells and that they do not circulate in blood. The prevailing convention is that BCP transit a CD34(+)CD19(-)10(+) early-B-->CD34(+)CD19(+)CD10(+) B-cell progenitor (pro-B)-->CD34(-)CD19(+)CD10(+) B-cell precursor (pre-B) differentiation pathway within BM. However, populations of CD34(+)CD10(+) and CD34(+)CD19(+) cells circulate in adult peripheral blood and neonatal umbilical cord blood (CB) that are operationally taken as BCPs on the basis of their phenotypes, although they have not been submitted to a systematic characterization of their gene expression profiles. Here, conventional CD34(+)CD19(+)CD10(+) and novel CD34(+)CD19(+)CD10(-) BCP populations are characterized in CB by single-cell sorting and multiplex analyses of gene expression patterns. Circulating BCP are Pax-5(+) cells that span the early-B, pro-B, and pre-B developmental stages, defined by the profiles of rearranged V-D-J(H), CD79, VpreB, recombination activating gene (RAG), and terminal deoxynucleotidyl transferase (TdT) expression. Contrary to the expectation, circulating CD34(+)CD19(-)CD10(+) cells are essentially devoid of Pax-5(+) BCP. Interestingly, the novel CD34(+)CD19(+)CD10(-) BCP appears to be the normal counterpart of circulating preleukemic BCPs that undergo chromosomal translocations in utero months or years before their promotion into infant acute lymphoblastic B-cell leukemia after secondary postnatal mutations. The results underscore the power of single-cell analyses to characterize the gene expression profiles in a minor population of rare cells, which has broad implications in biomedicine.

V(D)J recombinatorial repertoire diversification during intraclonal pro-B to B-cell differentiation

The initial B-cell repertoire is generated by combinatorial immunoglobulin V(D)J gene segment rearrangements that occur in a preferential sequence. Because cellular proliferation occurs during the course of these rearrangement events, it has been proposed that intraclonal diversification occurs during this phase of B-cell development. An opportunity to examine this hypothesis directly was provided by the identification of a human acute lymphoblastic leukemic cell line that undergoes spontaneous differentiation from pro-B cell to the pre-B and B-cell stages with concomitant changes in the gene expression profile that normally occur during B-cell differentiation. After confirming the clonality of the progressively differentiating cells, an analysis of immunoglobulin genes and transcripts indicated that pro-B cell members marked by the same DJ rearrangement generated daughter B cells with multiple V(H) and V(L) gene segment rearrangements. These findings validate the principle of intraclonal V(D)J diversification during B-cell generation and define a manipulable model of human B-cell differentiation.

The first 3 days of B-cell development in the mouse embryo

B-lineage-committed cells are believed to arise in the liver of mouse embryos at 14 days after coitus (dpc). However, pre-B-specific gene transcripts and DJH gene rearrangements have been detected in earlier, midgestation embryos. We describe here a population of c-kit(+)AA4.1(+)CD19(+)Pax5(+) cells present in the aorta-gonad-mesonephros (AGM) area and in the livers of 11-dpc mouse embryos. In contrast to multipotent c-kit(+)AA4.1(+)CD19(-) hematopoietic stem cells (HSCs), these c-kit(+)AA4.1(+)CD19(+) progenitors differentiated only to B-lineage cells in vitro. We propose that mouse embryonic B lymphopoiesis starts earlier than previously thought, at 10 to 11 dpc, both in liver and extra-liver hematopoietic sites. The B-cell differentiation program is not delayed with respect to the emerging lymphohematopoiesis events in the midgestation mouse embryo (8-9 dpc).

Exploring lymphocyte differentiation pathways

Highlights in a 4-decade exploration of lymphocyte differentiation begin with comparative studies in birds and mammals leading to recognition of the separate T- and B-cell differentiation pathways and their cooperative interaction. The global effects of aborting IgM B-cell development with anti-mu antibodies indicated that B cells can undergo immunoglobulin isotype switching. A search for the mammalian bursa equivalent that began with an extended excursion through the gut-associated lymphoepithelial tissues ultimately led to the hematopoietic tissue origin of mammalian B cells. The identification of the precursors of B cells in hematopoietic tissues provided an expanded view of the life history of B cells. A recurring theme in this essay is the interplay between understanding normal lymphocyte differentiation and the defects that underlie immunodeficiency diseases and lymphoid malignancies.