A model of bursal colonization

In the chicken, and perhaps in all birds, the development of the cells which form antibodies, the B-cells, differs substantially from that in mammals. In birds, committed B-cells colonize a specialized organ, the bursa of Fabricius, which consists of some 10(4) follicles. Diversification, i.e., the development of the antibody repertoire, takes place in bursal follicles by a process termed "gene conversion." The avian bursa is easily accessible experimentally, and in the chicken, it has been the subject of extensive research. As an aid to experimentation in this field, we present here a formal mathematical model of bursal development. Formulae are derived which allow one to estimate the number and sizes of B-cell clones in bursal follicles, and hence the size of the overall antibody repertoire. Particular attention is paid to the problem of estimating experimental errors.     

Marek’s disease virus prolongs survival of primary chicken B-cells by inducing a senescence-like phenotype

Marek’s disease virus (MDV) is an alphaherpesvirus that causes immunosuppression and deadly lymphoma in chickens. Lymphoid organs play a central role in MDV infection in animals. B-cells in the bursa of Fabricius facilitate high levels of MDV replication and contribute to dissemination at early stages of infection. Several studies investigated host responses in bursal tissue of MDV-infected chickens; however, the cellular responses specifically in bursal B-cells has never been investigated. We took advantage of our recently established in vitro infection system to decipher the cellular responses of bursal B-cells to infection with a very virulent MDV strain. Here, we demonstrate that MDV infection extends the survival of bursal B-cells in culture. Microarray analyses revealed that most cytokine/cytokine-receptor-, cell cycle- and apoptosis-associated genes are significantly down-regulated in these cells. Further functional assays validated these strong effects of MDV infections on cell cycle progression and thus, B-cell proliferation. In addition, we confirmed that MDV infections protect B-cells from apoptosis and trigger an accumulation of the autophagy marker Lc3-II. Taken together, our data indicate that MDV-infected bursal B-cells show hallmarks of a senescence-like phenotype, leading to a prolonged B-cell survival. This study provides an in-depth analysis of bursal B-cell responses to MDV infection and important insights into how the virus extends the survival of these cells.     

The origin of IgG-containing cells in the bursa of Fabricius

The bursa of Fabricius of the chicken is known as a primary lymphoid organ for B-cell development. Morphologically, the origin of IgG-containing cells in the bursa has not been clear until now, because abundant maternal IgG (MIgG) is transported to the chick embryo and distributed to the bursal tissue around hatching. Thus, it has been difficult to find out whether these cells themselves biosynthesize IgG or if they acquire MIgG via attachment to their surface. Our present study employing in situ hybridization clarified that IgG-containing cells in the medulla of bursal follicles did not biosynthesize IgG. To study the role of MIgG in the development of those IgG-containing cells, MIgG-free chicks were established from surgically bursectomized hen (SBx-hen). We found that, on the one hand, deprivation of MIgG from chicks completely inhibited the development of IgG-containing cells in the medulla after hatching. On the other hand, administration of MIgG to MIgG-free chicks recovered the emergence of those cells. In addition, we observed that those cells did not bear a B-cell marker and possessed dendrites with aggregated IgG. These results demonstrate that IgG-containing cells in the medulla are reticular cells that capture aggregated MIgG. Moreover, we show that the isolation of the bursa from environmental stimuli by bursal duct ligation (BDL) suppressed the development of IgG-containing cells after hatching. Thus, it is implied that environmental stimulations play a key role in MIgG aggregations and dendritic distributions of aggregated MIgG in the medulla after hatching.     

Insight into lymphoid development by gene expression profiling of avian B cells

The avian immune system provides an excellent model to track B-cell development from prebursal stem cells throughout B-cell differentiation and maturation. Bursal B cells are uniquely positioned at the crossroads of B-cell development, having properties of both stem cells and of mature B cells, as demonstrated by their ability to reconstruct the bursal B-cell compartment and to express and diversify the B-cell receptor at their cell surface. To understand avian B-cell development better, we determined the gene expression profile of different B-cell stages using a bursal expressed sequence tag array. The expression profile of bursal B cells reveals the presence of factors associated with B-cell signaling and defines novel B-cell-specific genes. Genes associated with proliferation, apoptosis, DNA repair and recombination are abundantly expressed. The expression profile of the DT40 cell line is most similar to bursal B cells rather than to other stages of B-cell development, confirming the suitability of DT40 for studies of B-cell physiology. Interestingly, prebursal stem cells express genes involved in B-cell receptor signaling, although they express only low levels of immunoglobulin genes. This suggests that B-cell receptor-mediated selection is present before bursal colonization. The gene expression signatures of germinal centers and cells of the Harderian gland indicate that evolutionarily conserved genetic programs regulate B-cell activation and terminal differentiation.Electronic Supplementary Material Supplementary material is available in the online version of this article atK. Koskela, P. Kohonen and P. Nieminen contributed equally to this work     

Early Events Associated with Infection of Epstein-Barr Virus Infection of Primary B-Cells

Epstein Barr virus (EBV) is closely associated with the development of a vast number of human cancers. To develop a system for monitoring early cellular and viral events associated with EBV infection a self-recombining BAC containing 172-kb of the Epstein Barr virus genome BAC-EBV designated as MD1 BAC (Chen et al., 2005, J.Virology) was used to introduce an expression cassette of green fluorescent protein (GFP) by homologous recombination, and the resultant BAC clone, BAC-GFP-EBV was transfected into the HEK 293T epithelial cell line. The resulting recombinant GFP EBV was induced to produce progeny virus by chemical inducer from the stable HEK 293T BAC GFP EBV cell line and the virus was used to immortalize human primary B-cell as monitored by green fluorescence and outgrowth of the primary B cells. The infection, B-cell activation and cell proliferation due to GFP EBV was monitored by the expression of the B-cell surface antigens CD5, CD10, CD19, CD23, CD39, CD40 , CD44 and the intercellular proliferation marker Ki-67 using Flow cytometry. The results show a dramatic increase in Ki-67 which continues to increase by 6–7 days post-infection. Likewise, CD40 signals showed a gradual increase, whereas CD23 signals were increased by 6–12 hours, maximally by 3 days and then decreased. Monitoring the viral gene expression pattern showed an early burst of lytic gene expression. This up-regulation of lytic gene expression prior to latent genes during early infection strongly suggests that EBV infects primary B-cell with an initial burst of lytic gene expression and the resulting progeny virus is competent for infecting new primary B-cells. This process may be critical for establishment of latency prior to cellular transformation. The newly infected primary B-cells can be further analyzed for investigating B cell activation due to EBV infection.     

Immune complexes of E. coli antigens and maternal IgG in the bursa of Fabricius

The bursa of Fabricius of the chicken is known to be both a primary lymphoid organ and a secondary lymphoid tissue. Bursal follicles are equipped with antigen-trapping follicle-associated epithelium. However, bioactive antigens such as protein and bacteria have not been detected in the bursal parenchyma. By immunoperoxidase staining with a polyspecific antibody (Ab) against Escherichia coli, we detected aggregated E. coli antigens in the medulla of bursal follicles after hatching. The distribution of aggregated E. coli antigens is restricted to the medulla of bursal follicles. The antigens are not found in the spleen or the parenchyma of the caecal tonsil. The bursa is thus a trapping site for E. coli antigens from the external environment. Furthermore, two-color immunostaining clarified that these antigens form immune complexes with maternal IgG (MIgG) and are retained by reticular cells. Additionally, immune complexes in the bursa were shown to induce the rapid development of serum IgM Ab for indigenous E. coli. Our results suggest that immune complexes of MIgG and environmental antigens in the medulla of bursal follicles exert positive effects on B-cell differentiation in the bursa in situ.     

Identification of a chicken CLEC-2 homologue, an activating C-type lectin expressed by thrombocytes

Receptors on natural killer (NK) cells are classified as C-type lectins or as Ig-like molecules, and many of them are encoded by two genomic clusters designated natural killer gene complex (NKC) and leukocyte receptor complex, respectively. Here, we describe the analysis of an NKC-encoded chicken C-type lectin, previously annotated as homologue to CD94 and NKG2 and thus designated chicken CD94/NKG2. To further elucidate its potential function on NK cells, we produced a specific mab by immunizing with stably transfected HEK293 cells expressing this lectin. Staining of various chicken tissues revealed minimal reactivity with bursal, or thymus cells. In peripheral blood mononuclear cell and spleen, however, the mab reacted with virtually all thrombocytes, whereas most NK cells in organs such as embryonic spleen, lung and intestine were found to be negative. These findings indicate that the gene may not resemble CD94/NKG2, but rather a CLEC-2 homologue, a claim further supported by sequence features such as an additional extracellular cysteine residue and the presence of a cytoplasmic motif known as a hem immunoreceptor tyrosine-based activation motif, found in C-type lectins such as Dectin-1, CLEC-2, but not CD94/NKG2. The biochemical analyses demonstrated that CLEC-2 is present on the cell surface as heavily glycosylated homodimer, which upon mab crosslinking induced thrombocyte activation, as measured by CD107 expression. These analyses reveal that the chicken NKC may not encode NK cell receptor genes, in particular not CD94 or NKG2 genes, and identifies a chicken CLEC-2 homologue.     

Phenotype and topography of human thymic B cells. An immunohistologic study.

Using single and double labeling immunohistochemical techniques and a large panel of monoclonal antibodies against B-cell differentiation antigens, including those newly defined at the Fourth International Leucocyte Typing Workshop, we have examined the immunophenotype and tissue distribution of human thymic B-cells. The existence of a distinct B-cell population as a constant constituent of the thymic microenvironment has been noted only recently. We found a significant population of B-lymphocytes in the thymic medulla expressing the B-cell restricted antigens CD19, CD20, CD22, CD37, CD72, CD76 and IgM and IgD. As with other extrafollicular B-lymphocytes, they differ significantly from both follicle mantle and germinal center cells in morphology and immunophenotype, which points to alternative modes of B-cell differentiation. Thymic B-cells themselves show considerable heterogeneity and a subpopulation with dendritic features and the expression of CD23 has been referred to as "asteroid" cells. Their close association with T-cells and medullary epithelial cells points to a functional role for B-cells in the thymus. A second population of B-lymphocytes together with frequent lymph follicles is found within the extrathymic perviascular space. Though separated from the medulla by a layer of epithelial cells, a clear distinction between the B-cells of these two compartments is not always possible. The intramedullary B-cell compartment shows a parallel numeric increase with the occurrence of germinal centers in the perivascular space, mostly due to an accumulation of B-cells in the medulla adjacent to these lymph follicles. Thus a close relationship between the intra- and extramedullary B-cell population of the thymus seems likely.     

Comparison of adhesion mechanisms and surface protein expression in CD77-positive and CD77-negative Burkitt's lymphoma cells.

The Burkitt lymphoma-derived Daudi cell line is often used as an in vitro model for germinal center B-cell function. Globotriaosyl ceramide (CD77), a marker for germinal center B-cells, is present on Daudi cells but is deficient in the Daudi-derived mutant VT500 cell line. Previous results showed a correlation in these cells between CD77 expression and expression of the B-cell protein CD19 and indicated that CD19/CD77 interaction is a mechanism for B-cell adhesion. Roles for CD77 in IFN-alpha-induced growth inhibition and anti-viral activity also have been described previously. Through flow cytometric analysis and adhesion assays, we investigated whether expression of CD77 was required for cell adhesion pathways induced by IFN or antibodies against additional B-cell surface molecules: CD20, CD22, CD38, CD40, CD81 and HLA-D proteins. In contrast to the pronounced homotypic adhesion induced by treatment with interferon-alpha in Daudi cells, no increase in adhesion was observed in IFN-treated VT500 cells. Of the B-cell proteins tested, only CD22-mediated adhesion and surface expression was stronger in Daudi than in VT500 cells. These results indicate that CD77 may be required for IFN and CD22-associated adhesion pathways, but CD77 is not a universal component of adhesion pathways in these cells.     

Immunohistochemical characteristics of chicken spleen ellipsoids using newly established monoclonal antibodies

Ellipsoids, the extra-vasculature sites surrounding penicilliary capillaries of the chicken spleen, play critical roles in the immune response and also in the clearance of pathogens or other particles. The meshwork of ellipsoids is formed by fibroblastic reticular cells. To characterize ellipsoidal reticular cells, a series of monoclonal antibodies against the chicken spleen have been developed. Of these antibodies, CSA-1 antibody reacts with fibroblastic reticular cells in ellipsoids and with endothelial cells. The reticular nature of positive cells in ellipsoids is indicated by immuno-electron microscopy, and by double-staining with anti-heat-shock protein 47 kDa (hsp47) antibody. The reaction of CSA-1 with reticular cells is limited in ellipsoids; CSA-1 does not react with reticular cells in other lymphoid organs. These findings indicate that ellipsoidal reticular cells share the antigen with endothelial cells. Ontogenic studies reveal that, on embryonic day 18, the development of ellipsoids is completed, penicilliary capillaries become fenestrated, and CSA-1 expression in ellipsoids begins. These findings suggest that CSA-1 is expressed on the cell surface of ellipsoidal reticular cells once they are exposed to blood flow.     

Phenotype and topography of human thymic B cells

Using single and double labeling immunohistochemical techniques and a large panel of monoclonal antibodies against B-cell differentiation antigens, including those newly defined at the Fourth International Leucocyte Typing Workshop, we have examined the immunophenotype and tissue distribution of human thymic B-cells. The existence of a distinct B-cell population as a constant constituent of the thymic microenvironment has been noted only recently. We found a singificant population of B-lymphocytes in the thymic medulla expressing the B-cell restricted antigens CD19, CD20, CD22, CD37, CD72, CD76 and IgM and IgD. As with other extrafollicular B-lymphocytes, they differ significantly from both follicle mantle and germinal center cells in morphology and immunophenotype, which points to alternative modes of B-cell differentiation. Thymic B-cells themselves show considerable heterogeneity and a subpopulation with dendritic features and the expression of CD23 has been referred to as “asteroid” cells. Their close association with T-cells and medullary epithelial cells points to a functional role for B-cells in the thymus. A second population of B-lymphocytes together with frequent lymph follicles is found within the extrathymic perviascular space. Though separated from the medulla by a layer of epithelial cells, a clear distinction between the B-cells of these two compartments is not always possible. The intramedullary B-cell compartment shows a parallel numeric increase with the occurrence of germinal centers in the perivascular space, mostly due to an accumulation of B-cells in the medulla adjacent to these lymph follicles. Thus a close relationship between the intra-and extramedullary B-cell population of the thymus seems likely. Presented in part in Leucocyte Typing IV (1989) Knapp W et al. (eds) Oxford University Press, Oxford, pp 221–222     

Tissue-Specific B-Cell Dysfunction and Generalized Memory B-Cell Loss during Acute SIV Infection

Background

Primary HIV-infected patients display severe and irreversible damage to different blood B-cell subsets which is not restored by highly efficient anti-retroviral therapy (HAART). Because longitudinal investigations of primary HIV-infection is limited by the availability of lymphoid organs, we studied the tissue-specific B-cell dysfunctions in acutely simian immunodeficiency virus (SIV) mac251-infected Cynomolgus macaques.

Methods and Findings

Experiments were performed on three groups of macaques infected for 14, 21 or 28 days and on three groups of animals treated with HAART for two-weeks either initiated at 4 h, 7 or 14 days post-infection (p.i.). We have simultaneously compared changes in B-cell phenotypes and functions and tissue organization of B-cell areas in various lymphoid organs. We showed that SIV induced a steady decline in SIgG-expressing memory (SIgD⁻CD27⁺) B-cells in spleen and lymph nodes during the first 4 weeks of infection, concomitant to selective homing/sequestration of B-cells to the small intestine and spleen. SIV non-specific Ig production was transiently increased before D14p.i., whereas SIV-specific Ig production was only detectable after D14p.i., coinciding with the presence of CD8⁺ T-cells and IgG-expressing plasma cells within germinal centres. Transient B-cell apoptosis on D14p.i. and commitment to terminal differentiation contributed to memory B-cell loss. HAART abrogated B-cell apoptosis, homing to the small intestine and SIV-specific Ig production but had minimal effect on early Ig production, increased B-cell proportions in spleen and loss of memory B-cells. Therefore, virus–B-cell interactions and SIV-induced inflammatory cytokines may differently contribute to early B-cell dysfunction and impaired SIV/HIV-specific antibody response.

Conclusions

These data establish tissue-specific impairments in B-cell trafficking and functions and a generalized and steady memory B-cell loss in secondary lymphoid organs. Characterization of underlying mechanisms would be helpful in designing new therapeutic strategies to dampen B-cell activation and increases HIV/SIV specific antibody response.     

Expression of human B-cell specific receptor FCRL1 in normal individuals and in patients with autoimmune diseases

The comparative analysis of expression level of FCRL1 gene encoding human B-cell surface receptor in healthy individuals and patients with autoimmune diseases was carried out. For the expression estimation we used results of DNA dot-hybridization on the membranes, containing cDNA samples from subpopulations of blood cells of patients with autoimmune diseases. The quantitative estimation of hybridization signals showed that expression level of FCRL1 gene in peripheral blood B-lymphocytes was significantly higher in patients with a multiple sclerosis, lupus anticoagulans, Takayasu's arteritis and also in von Willebrand disease than in healthy individuals. FCRL1-specific monoclonal and polyclonal antibodies were raised. They were proven to detect FCRL1 in Western blotting, immunohistochemistry and flow cytometry. It was found that FCRL1 is expressed on the surface of CD19+ mature B-cells. In tonsil FCRL1-positive cells were located in crypt area: in mantle zone of secondary lymphoid follicles and among cells of lymphoepithelium. FCRL1-positive cells were also found in B-cell follicles of the spleen.     

Quail as the chimeric counterpart of the chicken: morphology and ontogeny of the bursa of Fabricius

The quail is the chimeric and parabiotic counterpart of the chicken, thus increasing the value of quail in the field of developmental biology. Quail bursa of Fabricius was studied by light microscopy, electron microscopy, and immunocytochemical methods. The basic cellular composition and structural framework are comparable with those of the chicken bursa. One of the major structural differences is the absence of the continuous cortico-medullary arch. In addition to the epithelial reticular cell the bursal secretory dendritic cell is the other medullary-specific bursal cell. The bursal secretory dendritic cell is a highly elongated cell which expresses vimentin intermediate filaments and produces secretory granules. The substance of the granules can be visualized by NIC2 monoclonal antibody, which was produced against guinea fowl bursal secretory dendritic cell. The released granular content appears on the lateral surface of the bursal secretory dendritic cell and is gradually solubilized. Thus, the NIC2-positive substance may occur in membrane-bound and solubilized forms in the isolated environment of the medulla. The bursal secretory dendritic cell establishes membrane contact areas with the B cells; therefore, they may influence B-cell maturation by cell contact and chemical (humoral) product. During embryogenesis bursal secretory dendritic cell precursors enter the epithelium and 1) induce epithelial bud formation, and 2) produce an NIC2-positive substance. Senescent bursal secretory dendritic cells can be phagocytic and migrate into the follicle-associated epithelium. This physiological turnover of the bursal secretory dendritic cell represents a novel pathway of macrophage formation from dendritic cells.     

Expression of human B-Cell specific receptor FCRL1 in healthy individuals and in patients with autoimmune diseases

The expression levels of the FCRL1 gene, which encodes a human B-cell surface receptor, were compared in healthy individuals and patients with autoimmune diseases. The expression levels were evaluated using DNA dot hybridization on membranes with spotted cDNA samples derived from blood-cell sub-populations of patients with autoimmune diseases. Quantification of the hybridization signals showed that FCRL1 expression in peripheral blood B-lymphocytes of patients with multiple sclerosis, lupus anticoagulants, Takayasu’s arteritis, and von Willebrand disease was significantly higher than in healthy individuals. Monoclonal and polyclonal FCRL1-specific antibodies that enable FCRL1 detection in Western blotting, immunohistochemistry, and flow-cytometry assays were generated. It was found that FCRL1 is expressed on the surfaces of mature CD19+ B-cells. In the tonsils, FCRL1-positive cells were located in the crypt area, i.e., in the mantle zone of secondary lymphoid follicles and among the cells of lymphoid epithelium. FCRL1-positive cells were also found in B-cell follicles of the spleen.     

CD79a detected by ZL7.4 separates chronic lymphocytic leukemia from mantle cell lymphoma in the leukemic phase.

Both B-cell chronic lymphocytic leukemia (CLL) and mantle cell lymphoma (MCL) are characterized by a lymphoproliferation of neoplastic CD5+ B-cells, but an accurate differential diagnosis between these two malignancies is vitally important for guiding treatment options. Because CD79a has been identified as a pan-B marker, we intended to use it in place of CD19 to identify B-cells and to use CD23 to distinguish between CLL and MCL in the leukemic phase. Anti-CD79a (clone ZL7.4) was used to detect the Igalpha/mb1 protein in fresh CD5+ B-lymphocytes by dual-channel flow cytometry. Expression of CD19 and CD23 were similarly assessed. As expected, CD19 was expressed in all specimens, whereas CD23 expression was zero in 3/4 MCLs, weak in 1/4 MCLs, and 2/8 CLLs (10-19%) and stronger in 6/8 CLLs (> or =45%). However, although all the CD19+/CD5+ cells of MCL expressed high CD79a levels, CD79a expression was negligible or absent in 8/8 CLL specimens (mean positivity for CD79a = 2.41 +/- 2.71%). CD79a (ZL7.4) levels may provide a more reliable distinction than CD23 levels between CLL and MCL. If these results hold up in a larger series, we recommend that the ZL7.4 antibody should be considered in routine marker panels for CLL and low-grade lymphoma.     

Tissue-specific expression of the human CD19 gene in transgenic mice inhibits antigen-independent B-lymphocyte development.

CD19 is a B-cell-specific member of the immunoglobulin superfamily expressed from early pre-B-cell development until plasma cell differentiation. In vitro studies demonstrate that the CD19 signal transduction molecule can serve as a costimulatory molecule for activation through other B-lymphocyte cell surface molecules. However, much remains to be known regarding how CD19 functions in vivo and whether CD19 has different roles at particular stages of B-cell differentiation. Therefore, transgenic mice overexpressing the human CD19 (hCD19) gene were generated to determine whether this transgene would be expressed in a B-lineage-specific fashion and to dissect the in vivo role of CD19 in B-cell development and activation. Expression of the human transgene product was specifically restricted to all B-lineage cells and appeared early in development as occurs with hCD19. In addition, expression of hCD19 severely impaired the development of immature B cells in the bone marrow, with dramatically fewer B cells found in the spleen, peripheral circulation, and peritoneal cavity. The level of hCD19 expressed on the cell surface correlated directly with the severity of the defect in different transgenic lines. These results demonstrate that the hCD19 gene is expressed in a lineage-specific fashion in mice, indicating that the hCD19 gene may be useful for mediating B-lineage-specific expression of other transgene products. In addition, these results indicate an important role for the lineage-specific CD19 molecule during early B-cell development before antigen-dependent activation.     

Characteristics of bursal T lymphocytes induced by infectious bursal disease virus

Infectious bursal disease virus (IBDV) is an avian lymphotropic virus that causes immunosuppression. When specific-pathogen-free chickens were exposed to a pathogenic strain of IBDV (IM), the virus rapidly destroyed B cells in the bursa of Fabricius. Extensive viral replication was accompanied by an infiltration of T cells in the bursa. We studied the characteristics of intrabursal T lymphocytes in IBDV-infected chickens and examined whether T cells were involved in virus clearance. Flow cytometric analysis of single-cell suspensions of the bursal tissue revealed that T cells were first detectable at 4 days postinoculation (p.i.). At 7 days p.i., 65% of bursal cells were T cells and 7% were B cells. After virus infection, the numbers of bursal T cells expressing activation markers Ia and CD25 were significantly increased (P<0.03). In addition, IBDV-induced bursal T cells produced elevated levels of interleukin-6-like factor and nitric oxide-inducing factor in vitro. Spleen and bursal cells of IBDV-infected chickens had upregulated gamma interferon gene expression in comparison with virus-free chickens. In IBDV-infected chickens, bursal T cells proliferated in vitro upon stimulation with purified IBDV in a dose-dependent manner (P<0.02), whereas virus-specific T-cell expansion was not detected in the spleen. Cyclosporin A treatment, which reduced the number of circulating T cells and compromised T-cell mitogenesis, increased viral burden in the bursae of IBDV-infected chickens. The results suggest that intrabursal T cells and T-cell-mediated responses may be important in viral clearance and promoting recovery from infection.     

CD2 is expressed by a subpopulation of normal B cells and is frequently present in mature B-cell neoplasms

BACKGROUND: CD2 is expressed by T and natural killer (NK) cells and has been reported in T/NK cell lineage neoplasms as well as in immature B-lymphoblastic and myeloid leukemias. Although CD2+ B-cells have been identified in normal fetal and postnatal thymus, they have not been reported in adults. METHODS: We retrospectively reviewed flow cytometric immunophenotypic data on consecutive low-grade B-cell leukemias and lymphomas to investigate the frequency of CD2 expression. We also reviewed samples from normal healthy donors to determine whether there is a normal CD2+ B-cell population. RESULTS: CD2 expression (partial or complete) was observed in 13 of 83 (16%) chronic lymphocytic leukemias (CLL), 16 of 29 (55%) follicle center lymphomas (FCL), 3 of 12 (25%) hairy cell leukemias (HCL), 0 of 6 mantle cell lymphomas (MCL), 8 of 28 (29%) large cell lymphomas (LCL), and in 0 of 5 marginal zone/mucosa-associated lymphoid tissue lymphomas (MZL/MALT). We determined that 5.74 +/- 2.46% (mean +/- SD) of normal peripheral blood B cells and 6.48 +/- 1.62 % (mean +/- SD) of normal bone marrow B cells coexpress CD2. CONCLUSIONS: CD2 expression in B-cell neoplasia is a more prevalent phenomenon than previously appreciated. Normal CD2+ B-cell populations are observed in adults and may represent the nonmalignant counterpart of CD2+ B-cell neoplasms.