scholarly journals Molecular definition of the germinal centre stage of B–cell differentiation

2001 ◽  
Vol 356 (1405) ◽  
pp. 83-89 ◽  
Author(s):  
Chi Ma ◽  
Louis M. Staudt
Keyword(s):  
Gene Expression ◽  
Cell Differentiation ◽  
B Cells ◽  
B Cell ◽  
Expression Analysis ◽  
Peripheral Blood ◽  
Gene Expression Analysis ◽  
Gene Expression Signature ◽  
Germinal Centre ◽  
B Cell Differentiation

Genomic–scale gene expression analysis provides views of biological processes as a whole that are difficult to obtain using traditional single–gene experimental approaches. In the case of differentiating systems, gene expression profiling can define a stage of differentiation by the characteristic expression of hundreds of genes. Using specialized DNA microarrays termed ‘Lymphochips’, gene expression during mature B–cell differentiation has been defined. Germinal centre B cells represent a stage of differentiation that can be defined by a gene expression signature that is not shared by other highly proliferative B–cell populations such as mitogenically activated peripheral blood B cells. The germinal centre gene expression signature is maintained to a significant degree in lymphoma cell lines derived from this stage of differentiation, demonstrating that this gene expression programme does not require ongoing interactions with other germinal centre cell types. Analysis of representative cDNA libraries prepared from resting and activated peripheral blood B cells, germinal centre centroblasts, centrocytes and tonsillar memory B cells has confirmed and extended the results of DNA microarray gene expression analysis.

Gene Expression in Leukemic Blasts Persisting at Day 8 of Induction Therapy in Childhood ALL Displays a Common Shift towards Terminally Differentiated B Cells and a Cytoreduction-Associated Impairment of the Translational Machinery.

Blood ◽  
2005 ◽  
Vol 106 (11) ◽  
pp. 537-537
Author(s):  
Peter Rhein ◽  
Stefanie Scheid ◽  
Richard Ratei ◽  
Christian Hagemeier ◽  
Karl Seeger ◽  
...  
Keyword(s):  
Gene Expression ◽  
Cell Differentiation ◽  
B Cells ◽  
B Cell ◽  
Induction Therapy ◽  
Peripheral Blood ◽  
Therapy Resistance ◽  
B Cell Differentiation ◽  
Translational Machinery ◽  
Blast Cells

Abstract In childhood acute lymphoblastic leukemia (ALL), persistence of leukemic blasts during therapy is of crucial prognostic significance. To approach the mechanisms of therapy resistance, we addressed genome-wide gene expression in blasts persisting after one week of induction therapy (day 8 blasts) and their molecular signatures as compared with blast cells at initial diagnosis (day 0 blasts). In order to approach this issue experimentally, a procedure has been established including flow sorting of leukemic blasts by their leukemia-associated immunophenotype and preparation of cRNA, starting from a small number of cells. Blast cells from 12 patients with precursor B-cell ALL were investigated using Affymetrix HG U133A microarrays, and genes commonly up- or down-regulated in blast cells under therapy were identified in matched pairs of day 8 and day 0 samples. In spite of the heterogeneous clinical features of the patients (mean rate of cytoreduction after 7 days of initial therapy = 82%, range between 33% and 99%), we were able to determine a set of 310 genes whose expression was commonly changed between day 8 and day 0 with an estimated false discovery rate of 0.05. The identified set of genes indicated inhibited cell cycling, reduced metabolism, and expression changes of multiple factors related to B-cell differentiation. These changes collectively suggested that gene expression in day 8 blasts is shifted towards resting mature B cells. To test this hypothesis, we isolated normal B cells from peripheral blood samples of leukemic patients and compared their gene expression to that of leukemic blasts using Principal Component Analysis (PCA). PCA revealed that day 8 samples are positioned between day 0 samples and normal B-cell samples, and statistical significance of this observation could be established using the Jonckheere-Terpstra test. Changes of B-cell differentiation markers on protein level supported this finding. In addition, we analyzed all genes with regard to the correlation of their expression changes with the rates of cytoreduction in peripheral blood. We observed differential impairment of the key components of the translational machinery including ribosome, eukaryotic 43S preinitiation complex and eukaryotic 48S initiation complex. Overall, expression levels of these factors decreased in therapy-sensitive patients but did not change in therapy-resistant patients. Taken together, investigation of leukemia cells persisting during therapy identifies common and individual expression changes which may potentially affect sensitivity towards anti-leukemic agents and offers new insights into the mechanisms of therapy resistance in ALL.

scholarly journals An IRF4-MYC-mTORC1 integrated pathway controls cell growth and the proliferative capacity of activated B cells during B cell differentiation in vivo

2021 ◽  
Author(s):  
Dillon G Patterson ◽  
Anna K Kania ◽  
Madeline J Price ◽  
James R Rose ◽  
Christopher D Scharer ◽  
...  
Keyword(s):  
Gene Expression ◽  
Cell Differentiation ◽  
B Cells ◽  
Cell Growth ◽  
B Cell ◽  
Proliferative Response ◽  
Cell Activation ◽  
B Cell Differentiation ◽  
B Cell Activation

Cell division is an essential component of B cell differentiation to antibody-secreting plasma cells, with critical reprogramming occurring during the initial stages of B cell activation. However, a complete understanding of the factors that coordinate early reprogramming events in vivo remain to be determined. In this study, we examined the initial reprogramming by IRF4 in activated B cells using an adoptive transfer system and mice with a B cell-specific deletion of IRF4. IRF4-deficient B cells responding to influenza, NP-Ficoll and LPS divided, but stalled during the proliferative response. Gene expression profiling of IRF4-deficient B cells at discrete divisions revealed IRF4 was critical for inducing MYC target genes, oxidative phosphorylation, and glycolysis. Moreover, IRF4-deficient B cells maintained an inflammatory gene expression signature. Complementary chromatin accessibility analyses established a hierarchy of IRF4 activity and identified networks of dysregulated transcription factor families in IRF4-deficient B cells, including E-box binding bHLH family members. Indeed, B cells lacking IRF4 failed to fully induce Myc after stimulation and displayed aberrant cell cycle distribution. Furthermore, IRF4-deficient B cells showed reduced mTORC1 activity and failed to initiate the B cell-activation unfolded protein response and grow in cell size. Myc overexpression in IRF4-deficient was sufficient to overcome the cell growth defect. Together, these data reveal an IRF4-MYC-mTORC1 relationship critical for controlling cell growth and the proliferative response during B cell differentiation.

scholarly journals Selection at Multiple Checkpoints Focuses VH12 B Cell Differentiation toward a Single B-1 Cell Specificity

1999 ◽  
Vol 190 (7) ◽  
pp. 903-914 ◽  
Author(s):  
Calin Tatu ◽  
Jian Ye ◽  
Larry W. Arnold ◽  
Stephen H. Clarke
Keyword(s):  
Gene Expression ◽  
Cell Differentiation ◽  
B Cells ◽  
B Cell ◽  
High Frequency ◽  
Clonal Expansion ◽  
Selective Advantage ◽  
B Cell Differentiation ◽  
Cell Specificity ◽  
Selective Elimination

Phosphatidyl choline (PtC)-specific B cells segregate to the B-1 subset, where they comprise up to 10% of the B-1 repertoire. About half express VH12 and Vκ4/5H and are restricted in VHCDR3. We have previously reported that anti-PtC VHCDR3 is enriched among VH12-expressing cells by selective elimination of pre-B cells. We report here a bias for Vκ4/5H expression among VH12-expressing B cells, even among those that do not bind PtC and are not B-1. This is due in part to an inability of VH12 to associate with many light (L) chains but must also be due to a selective advantage in survival or clonal expansion in the periphery for Vκ4/5H-expressing cells. Thus, the bias for Vκ4/5H expression is independent of PtC binding, and, as segregation to B-1 occurs after Ig gene expression, it precedes segregation to the B-1 subset. In 6-1 mice, splenic B-1 cells reside in follicles but segregate to follicles distinct from those that contain B-2 cells. These data indicate that selection at multiple developmental checkpoints ensures the co-expression of an anti-PtC VHCDR3 and L chain in a high frequency of VH12 B cells. This focus toward specificity for PtC facilitates the development of a large anti-PtC B-1 repertoire.

EBV MicroRNA Expression in Virus Driven B-Cell Differentiation and Lymphomagenesis.

Blood ◽  
2009 ◽  
Vol 114 (22) ◽  
pp. 93-93
Author(s):  
Jamie P Nourse ◽  
Pauline Crooks ◽  
Do Nguyen Van ◽  
Kimberley Jones ◽  
Nathan Ross ◽  
...  
Keyword(s):  
Gene Expression ◽  
Cell Differentiation ◽  
B Cells ◽  
B Cell ◽  
Cell Lines ◽  
Phase 1 ◽  
Differentiation Process ◽  
B Cell Differentiation ◽  
B Cell Lymphomas

Abstract Abstract 93 Lymphomagenesis is a complex process, in part reflecting the nature of the transforming event, as well as the developmental stage of the cell. In the B-cell differentiation represents a continuum that is initiated when a naïve B-cell encounters antigen, undergoes a germinal centre (GC) reaction and ends with terminal differentiation into either a memory or plasma B-cell. Interruption of this process by a transforming event may result in a clonal proliferation where differentiation of the cell is blocked at this stage. The majority of B-cell lymphomas are derived from GC or post-GC B-cells. As physiologically relevant human models that emulate the various stages of B-cell differentiation are lacking we rationalized that in-vitro utilization of the B-cell lymphotrophic Epstein-Barr virus (EBV) would provide insights into this process. In one scenario, EBV infects naïve B-cells and drives a differentiation process paralleling the GC reaction through a well-characterized series of latency gene expression programs. EBV is also implicated in a range of GC and post-GC derived B-cell lymphomas (including Burkitt's, Hodgkin's, PTLD and DLBCL). Using high efficiency EBV infection of isolated naïve B-cells from EBV seronegative subjects, we have demonstrated that EBV infection provides a highly relevant in-vitro model that accurately reflects three distinct phases in the GC differentiation process. Alterations in the expression of a broad range of genes associated with the differentiation of the naïve B-cell were observed within 24 hours of infection and within four days of infection a process exhibiting many similarities to the GC reaction had taken place. These included BCL6, the levels of which were rapidly down-regulated within 24 hours indicating activation of the naïve B-cell. Levels of the memory cell marker CD27 steadily increased over 24 to 96 hours, while BLIMP1 expression increased, peaking at 48 hours. An increase in AID expression over 8 to 48 hours was consistent with somatic hypermutation and isotype switching. Finally a dramatic elevation in expression of the GC associated oncogene LMO2 was observed after two days followed by an equally dramatic downregulation after two weeks. Within two weeks of infection (phase 1), B-cells progressed through a GC-like phase followed by a one week transition state (phase 2) after which continued culture resulted in further differentiation to cells with the phenotypic hallmarks of post-GC cells (phase 3). MicroRNAs (miRNAs) are small non-coding RNAs, which act as negative regulators of gene expression. miRNA expression reflects the developmental lineage and differentiation state of several human cancers and over-expression is implicated in lymphomagenesis. They are also associated with the development of the GC reaction. EBV expresses at least 39 unique miRNAs from the BART and BHRF1 clusters within the viral genome. These EBV miRNAs are differentially expressed in tumour cell lines, suggesting roles during EBV-driven B-cell differentiation and lymphomagenesis. The relationship between EBV miRNAs and the kinetics of EBV driven B-cell differentiation has not been characterized. In our model we find distinct miRNA expression kinetics, coincidental with gene expression changes during B-cell differentiation, suggesting that these regulatory molecules may be involved in the GC process. Although a small number of EBV miRNAs were expressed at low levels early in the GC-like phase 1, the majority were up-regulated during the transition phase 2, exhibiting a subsequent partial down-regulation in the post-GC-like phase 3. The three phases were coincident with differential BART and BHRF1 promoter usage and alternate splicing. Strikingly, application of the infection model to primary patient samples and lymphoma cell-lines revealed that lymphomas clustered within distinct phases, reflecting the full continuum of the B-cell differentiation process. Interestingly, the majority of PTLD samples clustered within the transition phase, whereas Burkitt's and Hodgkin's lymphoma sample segregated with the GC stage. Application of our gene expression and miRNA data to cell-lines and a range of GC and post-GC EBV-positive lymphomas of various histological types indicate that our B-cell differentiation model can be used to accurately classify B-cell lymphomas in a physiologically relevant manner according to the stage of arrested B-cell differentiation. Disclosures: No relevant conflicts of interest to declare.

scholarly journals Ultrastructural studies of human lymphoid cells. mu and J chain expression as a function of B cell differentiation.

1983 ◽  
Vol 158 (6) ◽  
pp. 1993-2006 ◽  
Author(s):  
I Hajdu ◽  
Z Moldoveanu ◽  
M D Cooper ◽  
J Mestecky
Keyword(s):  
Cell Differentiation ◽  
B Cells ◽  
Golgi Apparatus ◽  
B Cell ◽  
Peripheral Blood ◽  
Plasma Cells ◽  
Peripheral Blood Lymphocytes ◽  
B Cell Differentiation ◽  
J Chain ◽  
Stimulation Of

J chain expression was examined as a function of the stage in differentiation along the B cell axis in humans. Intracellular distribution of J and mu chains in leukemic HLA-DR+ null and pre-B cells, and in normal B cells stimulated with pokeweed mitogen (PWM) was determined by immunoelectron microscopy and radioimmunoassay (RIA). J chain was detected in leukemic null and pre-B cells on free and membrane-bound ribosomes in the cytoplasm, or on perinuclear cisternae. Mu chain was found on free ribosomes and ribosomal clusters in leukemic pre-B cells but was absent in the leukemic null cells. In pre-B cell lines, mu chain was seen within rough endoplasmic reticulum (RER) and the Golgi apparatus whereas J chain was not detected in these organelles. However, both mu and J chain were detected in RER and the Golgi apparatus of immature and mature plasma cells induced by PWM stimulation of normal peripheral blood lymphocytes. Low levels of J chain were also detected by RIA in lysates of leukemic null and pre-B cells. Most of the intracellular J chain became detectable after reduction and alkylation of cell lysates, and free J chain was not found in the culture supernatants. The amount of intracellular and secreted immunoglobulin-bound J chain increased dramatically after PWM stimulation of peripheral blood lymphocytes. The majority of J chain-positive cells seen over an 8 d culture interval were lymphocytes and lymphoblasts, while mu chain was found primarily in plasma cells. These results suggest that J chain expression precedes mu chain synthesis during B cell differentiation and that a combination of the two chains for secretion is not initiated until the onset of plasma cells maturation.

A Putative Role for VEGFR-1 (FLT-1) in B Cell Commitment and Differentiation.

Blood ◽  
2006 ◽  
Vol 108 (11) ◽  
pp. 1152-1152
Author(s):  
Rita Fragoso ◽  
Catia Igreja ◽  
Claudia Appleton ◽  
Alexandra Henriques ◽  
Nuno Clode ◽  
...  
Keyword(s):  
Bone Marrow ◽  
Cell Differentiation ◽  
B Cells ◽  
B Cell ◽  
Peripheral Blood ◽  
Myeloid Differentiation ◽  
B Cell Differentiation ◽  
Cd34 Cells ◽  
Cell Commitment

Abstract VEGF and its receptors are expressed in the hematopoietic system. A role for FLT-1 in particular was described in monocyte-macrophage migration and lineage differentiation (Sawano A et al, 2001), megakaryocytes maturation (Casella I et al, 2003) and dendritic cell differentiation (Dikov M et al, 2005). Given that the expression of this receptor in the lymphoid lineage is not known, we to studied FLT-1 expression and a putative function in normal lymphoid progenitors. To address this question we induced in vitro CD34+ cells differentiation into the B cell lineage using a well established assay (on S17 stromal cells). With this approach, we observed that FLT-1 is expressed throughout B cell differentiation increasing along the differentiation process, and reaching its highest at the “immature B cell” stage. We also neutralized FLT-1 during B cell differentiation in vitro. Surprisingly, in the presence of the FLT-1 neutralizing antibody (6.12 monoclonal Ab, from ImClone systems), at the end of the assays (4 different experiments) a significantly higher number of CD19+ cells (mainly immature B cells) were detected. Analyzing some of the transcription factors known to be involved in the commitment and differentiation of lymphoid B cells, we observed that the expression of PU.1, Pax5 and E47 was up-regulated by FLT-1 neutralization. Next, given that FLT-1 function was mainly associated with cell migration, and since it is expressed in B cells that are ready to exit the bone marrow into secondary lymphoid organs, we reasoned that FLT-1 might have a role in B cells exit from the bone marrow. For this purpose, we treated mice with the FLT-1 neutralizing Ab for 3 days and analyzed B cells levels in bone marrow and peripheral blood. FLT-1 neutralization led to a significant decrease (p<0.05) in B cells in the bone marrow and peripheral blood. Taken together, our data supports a clear role for FLT-1 in B cell commitment. To understand if VEGF/PlGF signalling through FLT-1 promotes myeloid differentiation, suppresses B cell differentiation or simply regulates the quiescent state of hematopoietic stem cells, we differentiated in vitro CD34+/FLT-1− cells and CD34+/FLT-1+ cells (10% of CD34+ cells) using the assay described above. Interestingly, CD34+/FLT-1− differentiation in vitro largely promoted B cell differentiation, while CD34+/FLT-1+ cells originated mostly myeloid cell differentiation. We are currently exploiting the molecular basis whereby FLT-1 signalling may impair B cells commitment and possibly promotes myeloid differentiation.

Aberrant Co-Expression of Key Transcription Factors BCL6, IRF4 and FOXP1 Are Frequently Observed in Diffuse Large B-Cell Lymphoma

Blood ◽  
2008 ◽  
Vol 112 (11) ◽  
pp. 3761-3761
Author(s):  
Maayke Boll ◽  
Sharon L Barrans ◽  
Charles S McManamy ◽  
Andrew S Jack
Keyword(s):  
Transcription Factors ◽  
Cell Differentiation ◽  
B Cells ◽  
B Cell ◽  
Cell Lymphoma ◽  
B Cell Lymphoma ◽  
Germinal Centre ◽  
B Cell Differentiation ◽  
Large B Cell Lymphoma ◽  
Large B Cell

Abstract Diffuse Large B-cell Lymphoma (DLBCL) is classified into germinal centre (GCB) and activated B-cell (ABC) type by comparison with the phenotype of normal B-cells. Using single-color immunocytochemistry, tumors can be classified using a simple algorithm based on the expression of CD10, BCL6 and IRF4. This classification may have prognostic relevance and correlates with balanced translocations involving the immunoglobulin locus. However, the phenotypic differences between normal and neoplastic cells may be of greater relevance to understanding the pathogenesis of DLBCL and in developing effective diagnostic techniques. To investigate this we examined the co-expression of BCL6, IRF4 and FOXP1. These are key transcription factors that regulate the process of germinal centre and post germinal centre B-cell differentiation. Abnormal co-expression of these molecules would be expected to have major effects on the overall cellular phenotype. A multi-color immunofluorescence (MCIF) technique was developed that allowed the co-expression of these markers to be assessed in relation to the PAX5 positive B-cell population. The use of a multi-color technique allows the distinction between co-expression at the level of individual cells and differentiation within the tumor as a whole. We first determined the pattern of expression of these transcription factors in normal B-cells. In reactive lymph nodes the expression of BCL6, IRF4 and FOXP1 was almost mutually exclusive with only a small proportion of co-expressing cells. In a series of 61 DLBCL co-expression of both BCL6/IRF4 and IRF4/FOXP1 was found in 41/61 (67%) of the cases. In most of these cases the level of co-expression was greater than 50% of the PAX5 positive large lymphoid cells. Co-expression was not present in 11/61 (18%) of the tumors. In the remaining cases there was co-expression of either BCL6/IRF4 or IRF4/FOXP1. There was no correlation between the occurrence of co-expression of these combinations of transcription factors and the expression of CD10 or the classification into GCB and ABC phenotypes. In 16 of the cases the sample used was a small needle core biopsy in which assessment of nodal architecture was impossible. In these cases it was possible to confidently determine the presence of abnormal co-expression in 14/16 (87.5%) of the cases. One explanation for the aberrant co-expression of BCL6 and IRF4 in DLBCL would be the presence of a 3q27 rearrangement leading to dysregulation of BCL6 expression. However, in this series there was no correlation between BCL6/IRF4 co-expression and abnormalities of 3q27 detected by interphase FISH. These results show that in the majority of cases of DLBCL the key transcription factors regulating post germinal centre B-cell differentiation are expressed in combinations not seen in normal B-cells. This is likely to be a central element in the pathogenesis of these tumors. The ability to reliably identify these abnormalities by MCIF has potential value in improving the reliability of diagnosis of DLBCL when only small biopsy samples are available and it is likely that this approach can be extended to other types of lymphoma.

Gene expression profiling of plasma cells and plasmablasts: toward a better understanding of the late stages of B-cell differentiation

Blood ◽  
2003 ◽  
Vol 102 (2) ◽  
pp. 592-600 ◽  
Author(s):  
Karin Tarte ◽  
Fenghuang Zhan ◽  
John De Vos ◽  
Bernard Klein ◽  
John Shaughnessy
Keyword(s):  
Gene Expression ◽  
Cell Differentiation ◽  
B Cells ◽  
B Cell ◽  
Plasma Cells ◽  
Close Contact ◽  
Expression Profiles ◽  
Principal Component ◽  
B Cell Differentiation

AbstractPlasma cells (PCs), the end point of B-cell differentiation, are a heterogeneous cell compartment comprising several cell subsets from short-lived highly proliferative plasmablasts to long-lived nondividing fully mature PCs. Whereas the major transcription factors driving the differentiation of B cells to PCs were recently identified, the subtle genetic changes that underlie the transition from plasmablasts to mature PCs are poorly understood. We recently described an in vitro model making it possible to obtain a large number of cells with the morphologic, phenotypic, and functional characteristics of normal polyclonal plasmablastic cells (PPCs). Using Affymetrix microarrays we compared the gene expression profiles of these PPCs with those of mature PCs isolated from tonsils (TPCs) and bone marrow (BMPCs), and with those of B cells purified from peripheral blood (PBB cells) and tonsils (TBCs). Unsupervised principal component analysis clearly distinguished the 5 cell populations on the basis of their differentiation and proliferation status. Detailed statistical analysis allowed the identification of 85 PC genes and 40 B-cell genes, overexpressed, respectively, in the 3 PC subsets or in the 2 B-cell subsets. In addition, several signaling molecules and antiapoptotic proteins were found to be induced in BMPCs compared with PPCs and could be involved in the accumulation and prolonged survival of BMPCs in close contact with specialized stromal microenvironment. These data should help to better understand the molecular events that regulate commitment to a PC fate, mediate PC maintenance in survival niches, and could facilitate PC immortalization in plasma cell dyscrasias.

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