Modulation of chronic lymphocytic leukemia cells by phorbol ester: increase in Ia expression, IgM secretion and MLR stimulatory capacity

When cultured with 12-O-tetradecanoylphorbol 13-acetate (TPA) at a concentration of 1.6 X 10(-7) M, chronic lymphocytic leukemia (CLL) cells differentiated into mature cells of B lineage and increased their expression of surface Ia antigens when compared with cells cultured in the absence of TPA. Concurrently, TPA enhanced the ability of CLL cells to stimulate in a mixed lymphocyte reaction (MLR). The events induced in vitro by TPA that are characteristic of B cell maturation included morphologic changes, reduction in surface immunoglobulin (Ig), appearance of cytoplasmic Ig, and secretion of IgM. The increase in Ia expression and the enhanced capacity to stimulate in an MLR after incubation with TPA might also be associated with maturation of the CLL cells. The changes induced in vitro by TPA in neoplastic B cells provide new information concerning the terminal events in normal B cell differentiation.     

Expression of membrane activation antigens on murine B lymphocytes stimulated with lipopolysaccharide

The expression of two membrane glycoproteins, RL388 antigen and transferrin receptor (TfR), was examined on murine B cells stimulated with lipopolysaccharide (LPS) in vitro. Immunofluorescent staining with monoclonal antibodies and flow cytofluorometric analysis were used to monitor the expression of these markers as a function of the time in culture, the state of membrane Ia antigen expression, the position in cell cycle, and the degree of B-cell differentiation. Freshly explanted splenic B cells expressed low levels of RL388 antigen and TfR. Following LPS stimulation, increased expression of RL388 antigen was detectable by 8 to 12 hr of culture, a time span characterized by increased Ia antigen expression, blast transformation, and G0 to G1 phase transition. The increased expression of TfR was apparent later and correlated with entry into late G1 phase and the onset of S phase. LPS-stimulated cell cultures treated with actinomycin D (G0/G1 block) exhibited increased expression of Ia antigen, but neither RL388 antigen nor TfR, whereas hydroxyurea treatment (G1/S block) allowed expression of all three markers. These results indicate that hyperexpression of RL388 antigen and TfR occurs during G1 phase and that these events are subsequent to Ia antigen hyperexpression. Finally, B cells in late G1 through M phase of the cell cycle simultaneously express high levels of RL388 antigen and TfR. These findings suggest that the expression patterns of RL388 antigen and TfR might be useful parameters for defining compartments of the murine B-cell cycle.     

Long-term-cultured mouse B-lymphocyte line. II. Modulation of Ia-antigen expression on B-lymphocyte line

Mouse B-cell line, established by culturing anti-Thy-1 and complement-treated splenic B cells with concanavalin A-stimulated conditioned medium, expressed immunoglobulins and Ia antigens on its surface. The long-term-cultured B-cell line was split in two and maintained with or without 3300 R X-irradiated T-cell-depleted syngeneic splenic adherent cells (SAC). Interestingly, the B-cell line cultured without SAC lost its Ia antigen but not its Ig expression, whereas the cell line with SAC maintained both Ia and Ig expression. The ability to express Ia antigens was restored by culturing them only in the presence of Ia-positive feeder cells. Neither recombinant interferon-gamma or lectin-stimulated conditioned medium nor cell-free culture supernatant SAC had the ability to restore Ia antigen expression on the B-cell line. Incubation of Ia-negative B-cell line with phorbol esters restored the Ia expression. It is suggested that the expression of Ia antigen on B lymphocytes was controlled differently from that on macrophage lineage. The B-cell line expressing Ia antigens acts as stimulator cells for alloantigen-activated T lymphocytes and as antigen-presenting cells on the KLH-specific Ia-restricted proliferative T-cell clone in the presence of a specific antigen.     

B lymphocyte-associated antigens on terminal deoxynucleotidyl transferase-positive cells and pre-B cells in bone marrow of the rat

To investigate early stages of B lymphocytopoiesis in rat bone marrow (BM) before the expression of surface IgM (s mu), the populations of cytoplasmic mu-chain-positive (c mu+) pre-B cells and terminal deoxynucleotidyl transferase-positive (TdT+) cells were studied by double immunofluorescence microscopy. B lymphocytes that were s mu+ constituted 5%, c mu+s mu- pre-B cells 23%, and TdT+ cells 4% of nucleated cells in the BM of juvenile rats. TdT+ and pre-B cells ranged between 7 and 17 microns in diameter. TdT+ cells were slightly larger, with a modal diameter of 10.5 microns against 9 microns for pre-B cells. mu-Chains were absent from nearly all TdT+ cells. Their surface antigenic phenotype was studied by using a panel of mouse monoclonal antibodies (MAb) to rat B lymphocyte-associated antigens (Ig, Ia, and others) and T lymphocyte-associated antigens. Both pre-B cells and TdT+ lacked surface Ig and Ia but carried most of the other B lymphocyte-associated antigens analyzed. TdT+ and pre-B cells lacked those antigens found only on the T lineage. By using MAb HIS24 (detecting a non-Ig/Ia B lymphocyte-associated antigen) and fluorescence-activated cell sorting, TdT+ and pre-B cells were highly enriched. The results show that most TdT+ cells in rat BM are mu- but demonstrate strong similarity with pre-B cells in surface antigenic phenotype. Therefore, as suggested for man, a major proportion of rat BM TdT+ cells may be B lineage-cells before mu heavy chain gene expression.     

Studies of in vitro activation and differentiation of human B lymphocytes. I. Phenotypic and functional characterization of the B cell population responding to anti-Ig antibody

Investigation of the activation of splenic B cells by anti-immunoglobulin (Ig) antibody has enabled us to characterize the anti-Ig-responsive B cell and to analyze the phenotypic changes which accompany proliferation and differentiation. The anti-Ig antibody-responsive B cell population was characterized by the expression of high levels of the B2 antigen and represented approximately 40% of splenic B cells. Brisk mitogenesis which peaked at 3 to 4 days was induced by anti-Ig antibody. The proliferative phase was characterized phenotypically by a dramatic decline in B2 antigen expression, with most cells showing no detectable B2 by 4 days post-activation. The other hallmark of this phase was de novo expression of a group of "activation antigens." These included the B cell-restricted antigens B-LAST 1, BB1, and B5, and the T cell-associated interleukin 2 receptor and T12 antigens. Concomitantly, B1, B4, and Ia expression increased, the increase being roughly proportional to the increase in cell size. After day 4, the mitogenic response progressively diminished, while Ig synthesis increased. During this differentiation phase, cell surface antigens again displayed a distinct sequence of changes. The five activation antigens and the B1, B4, and Ia antigens began to decrease. However, two markers, T10 and PCA-1, which are found on plasmacytomas, appeared and their level of expression steadily increased. These changes and the appearance of morphologically identifiable plasma cells required the presence of T cells in this system. T cell supernatants alone induced Ig secretion but did not induce expression of PCA-1 or the appearance of cells with plasma cell morphology. The culture system developed in this study has allowed us to analyze the antigenic changes following activation by anti-Ig antibody. This sequence of changes has not only permitted the identification of antigens which, by their appearance at distinct stages may have an important role in proliferation and differentiation of B cells, but also provides us with the means of studying the function of each antigen.     

Differential effect of antigen-nonspecific T-cell factors and lipopolysaccharide on the Ia antigens and surface immunoglobulins of BALB/c lymphoma cell lines

In order to study the mechanism of B-cell differentiation using B lymphoid tumor cells as models, we investigated the effects of antigen-nonspecific T-cell factors in combination with lipopolysaccharide (LPS) on the expression of surface markers on B lymphoid cell lines. This study demonstrated that culture supernatant from concanavalin A-activated spleen cells (CAS) gave 2- to 3.5-fold enhancement of the expression of Ia antigens. The effect of CAS was dose dependent and as little as 2% CAS gave maximum enhancement of Ia antigen expression. The CAS effect was due to concanavalin A-activated cell products and was not due to the concanavalin A. The effects of allogeneic effect factor (AEF) on Ia antigens were similar to those of CAS. In contrast to CAS and AEF, LPS did not affect the expression of Ia antigens on ×16C 8.5. LPS enhanced 1.5- to 3-fold the expression of sIgM on this cell line. The expression of sIgM was minimally affected by T-cell factors; CAS induced 20 to 70% enhancement of sIgM expression while AEF induced no significant effects. This study showed that antigen-nonspecific factors (CAS and AEF) influenced mainly Ia expression on the B-cell lymphoma, ×16C 8.5, while LPS selectively affected sIgM expression. Therefore, it was concluded that the mechanisms by which B cells are activated by T-cell factors and mitogens are different.     

Level of mIa expression on mitogen-stimulated murine B lymphocytes is dependent on position in cell cycle

Using correlated flow cytometric analysis of cell surface Ia antigen expression (immunofluorescence) and cell cycle phase (pulse-width of axial light extinction), we have quantitated changes in expression of mIa antigen on murine B cells during progression through cell cycle. Our results indicate that density of mIa expressed on mitogen-stimulated B cells increases fourfold to fivefold during the transition from G0 to G1. By early S phase, mIa density has decreased by fourfold to fivefold relative to peak expression. This decrease becomes more evident by late S, G2, and M phases, when an eightfold decrease in mIa antigen density is observed relative to peak levels. This decrease results in mIa antigen expression lower than that of resting, unstimulated B cells. Therefore, maximum mIa antigen expression occurs during G0 to G1 transition and in early G1, when a requirement for I region-restricted, antigen-driven T cell help for thymus-dependent, antigen-driven B cell activation has been demonstrated.     

Membrane depolarization is induced in tolerant B lymphocytes by stimulation with antigen

Membrane depolarization is one of the earliest events in activation of cells by ligand receptor interaction. It is known that crosslinking of antigen-specific Ig receptors on B cells by antigen can induce membrane depolarization and subsequent Ia antigen expression on the cell surface. To determine whether a tolerance-inducing form of the antigen can also induce membrane depolarization after Ig receptor binding we used splenic B cells enriched for dinitrophenyl (DNP)-specific cells and determined relative membrane potential in these cells after binding of DNP-murine IgG2a (MGG) (tolerogen) or antigens (DNP-keyhole limpet hemocyanin (KLH) and DNP-Ficoll). Relative membrane potential was determined by loading the cells with the dye, 3.3-dipentyloxacarboxyanine (DiOC5(3)) after 2 hr incubation with ligand and determining relative fluorescence intensity on the fluorescence-activated cell sorter (FACS). Carriers alone did not depolarize these normal cell populations, but 100% of DNP-specific cells were depolarized by DNP-KLH and DNP-MGG while 85% were depolarized by DNP-Ficoll. To determine if tolerant B cells could be depolarized by antigen we induced tolerance in vitro or in vivo with DNP-MGG and measured the depolarization of DNP-specific B cells in response to antigens and tolerogen. DNP-specific B cells made tolerant by DNP-MGG underwent membrane depolarization when incubated with either DNP-KLH, DNP-MGG, or DNP-Ficoll but not with carriers alone. These data suggest that tolerogen induces membrane depolarization equally as well as antigen in normal cells. In addition, tolerant cells can be depolarized by Ig receptor crosslinking with either antigen or tolerogen. Thus, tolerance does not block the early membrane events induced by antigen in B cells.     

MHC-chromosome dosage effects: evidence for increased expression of Ia glycoprotein and alteration of B cell subpopulations in neonatal aneuploid chickens

Quantitative variation in the expression of MHC-encoded class II (Ia) glycoproteins has been associated with stages of lymphocyte development and a number of disease conditions. We have used an avian MHC dosage model to study the regulation of Ia expression and the effects of quantitative variation in membrane Ia on B-cell development. Lymphocyte membrane expression of Ia glycoprotein molecules and the frequency of small-versus-large lymphocytes were examined in trisomic line chickens containing either two (disomic), three (trisomic), or four (tetrasomic) copies of the microchromosome encoding the MHC. This was accomplished by quantitative laser flow cytometry analysis of bursa-resident B lymphocytes from neonatal trisomic line chickens. The aneuploids (trisomics and tetrasomics) expressed more cell surface Ia than did normal disomic birds. Furthermore, the aneuploids exhibited a greater frequency of small B lymphocytes as compared to disomic chickens. Dual parameter analysis of Ia. quantity and cell size was undertaken to study B lymphocyte subpopulations in these birds. It was observed that the aneuploids had altered frequencies of two distinct subpopulations of cells: (1) an increased percentage of small cells which express high levels of Ia antigen and (2) a decreased percentage of large cells which express medium levels of Ia antigen. These findings support the view that MHC class II genes are regulated and expressed in a dosage-dependent manner. Therefore, increases in the number of MHC copies per cell result in the increased expression of Ia glycoprotein on bursa-resident B cells. The stepwise increase in membrane Ia on trisomic and tetrasomic B cells is correlated, and perhaps casually linked, with progressive degrees of alteration of developing B cell subpopulations in the bursa of aneuploid chicks. These events may ultimately alter the humoral immunity of the aneuploid animals.     

The modulation of membrane Ia on human B lymphocytes

Using flow cytometry techniques, changes in surface Ia (DR and DS) expression on human B lymphocytes were correlated with changes in the cell cycle following stimulation with anti-mu. The effect of interleukin (IL)-1, IL-2, B-cell growth factor (BCGF), and interferons on Ia expression on resting B cells was also examined. A population of resting B lymphocytes was cultured in vitro with 100 micrograms/ml of anti-mu and immunofluorescently stained for DR and DS at various times following stimulation. Detectable increases in DR and DS expression were found within 8 hr, and the major increases (twofold and fourfold) in DR and DS expression occurred over the next 48 hr. Using cell cycle inhibitors and propidium iodide staining, it was demonstrated that the enhanced DR and DS expression following anti-mu stimulation began during G0 to G1 transition and increased as the cells progressed through G1 phase. During S and G2/M phases, there were minimal further increases in surface Ia. Although prolonged exposure of B cells to anti-mu was required for cellular activation, cell size enlargement, and progression into S phase, a brief exposure to anti-mu, insufficient for cellular activation, markedly enhanced Ia expression. Thus anti-mu-stimulated resting human B lymphocytes rapidly increase their surface Ia expression. This increase occurs predominantly prior to entrance into S phase and can occur in the absence of significant cellular activation. Interferons have been reported to modulate surface Ia expression on a human lymphoid cell line and on monocytes and supernatants with BCGF activity to enhance surface Ia expression on murine B cells; however, neither alpha-interferon, gamma-interferon, IL-1, IL-2, nor BCGF modified surface DR expression on normal resting human B cells.     

Interleukin 4 enhances the ability of antigen-specific B cells to form conjugates with T cells

T cell-B cell conjugates are formed when trinitrophenyl-specific B cells are exposed to trinitrophenyl-ovalbumin and ovalbumin-specific T hybridoma cells. The proportion of conjugates was increased two- to threefold when antigen-pulsed trinitrophenyl-specific B cells, but not T cells, were pre-exposed to interleukin 4. Antigen-specific B cells pretreated with antigen and interleukin 4 and cultured in the presence of specific T helper cells also produced a larger proportion of antibody-secreting cells as compared to cells pretreated with antigen alone. The interleukin 4-induced enhancement of T/B conjugate formation occurred over a wide range of antigen concentrations, was dependent on the concentration of interleukin 4, and was inhibited by the monoclonal anti-interleukin 4 antibody, 11B11. The importance of Ia antigens in the enhancement of conjugate formation and generation of antibody-secreting cells is suggested by a) the fact that the interleukin 4-mediated increase in the density of Ia antigens on the antigen-specific B cells correlated with their enhanced ability to form T/B conjugates, b) the kinetics of the interleukin 4-mediated increase in conjugate formation and surface Ia expression were similar, c) 10- to 20-fold higher concentrations of anti-I-A antibody were required to inhibit T/B conjugate formation by 50% with interleukin 4-treated antigen-specific B cells compared with untreated antigen-specific B cells, and d) interferon-gamma, which inhibits the interleukin 4-mediated increase in Ia antigens, inhibited the interleukin 4-induced enhancement of T/B conjugate formation. These results indicate that the interleukin 4-induced increase in the expression of Ia antigens on B cells plays an important role in the enhancement of T/B cell interactions and the subsequent differentiation of antigen-specific B cells into antibody-secreting cells.     

Measles virus infection of B lymphocytes permits cellular activation but blocks progression through the cell cycle.

Measles virus infection of unstimulated B lymphocytes suppresses both proliferation and differentiation into immunoglobulin-secreting cells. However, mitogenic stimulation of these infected cells results in cell volume enlargement, rapid RNA synthesis, and the expression of cell surface activation antigens 4F2, HLA-DS, and transferrin receptor. The cellular genes c-myc and histone 2B are induced during early G1 and S phase of the cell cycle, respectively, and viral RNA synthesis can be detected during this interval. However, total RNA synthesis is decreased at 48 h after stimulation, and the histone 2B RNA steady-state level at 48 h is fivefold less than that in uninfected cells. This sequence of events defines an arrest in the G1 phase of the cell cycle in measles virus-infected B cells.     

Immortalization of murine leukocytes by oncogenes. II. Phenotypic characterization of transformants immortalized by v-src or Ha-ras oncogenes: expression of B220, a B-cell lineage specific antigen

In the course of study to obtain murine dendritic cell lines using oncogenic retroviruses, we have established several immortalized cell lines with characteristics different from those of dendritic cells. The transformants were mainly round nonadherent cells, capable of growing in soft agar, and negative for nonspecific esterase activity. Profiles of cell surface antigens were examined by indirect immunofluorescence technique. The cell lines were positive for Fc receptor (2.4G2), J11d (J11d.2), and B220 (RA3-3A1/6.1) antigens and negative (or dull positive in small percentages) for Ia (M5/144.15.2), IL-2 receptor (3C7), Thy-1 (B5-5), Mac-1 (M1/70.-15.11.5), and macrophage (F4/80) antigens. They were negative for both surface and cytoplasmic immunoglobulins. Several clones were established from these transformant cell lines and cell surface antigens were examined. Antigenic profiles of these clones were very similar to those of the parental cell lines. Some of these clones, however, seemed to increase their Ia antigen expression. The results suggest that the transformants originated from early B-lineage cells.     

The distribution of blood group antigens in rodent epithelia

Summary The pattern of distribution of antigens cross-reacting with antibodies to human blood group antigens A and B and two precursor molecules was examined by immunofluorescence in the epidermis, oral mucosa and forestomach of rats and mice. Staining for blood group antigen A was negative. In all epithelia examined, blood group antigen B was present at the surface of basal and parabasal cells, and the H antigen at the surface of spinous cells. N-acetyllactosamine was present on the cell membranes in the upper spinous and granular cell layers of epidermis and forestomach epithelium and was not expressed in the oral epithelia except for a limited area in the dorsal tongue epithelium.Thus, the expression of antigen varies both regionally and, as earlier shown in human epithelium, with the stage of maturation of cells within a given epithelium. The observed sequence of expression of these antigens during maturation differs from that of human epithelia, but the present study provides a basis for further experimental studies of the role of cell surface antigens in epithelial homeostasis and maturation.     

Control of cell cycle entry and progression in mitogen-stimulated human B lymphocytes

Tonsillar B lymphocytes were stimulated to proliferate by the mitogenic combination of phorbol dibutyrate and ionomycin. Progression through the cell cycle was monitored by measurements of cellular DNA and RNA content using flow cytometry. Changes in surface expression of class II MHC antigens and CD20 antigen were also monitored as early parameters of B lymphocyte activation and cell cycle progression. The results showed that about 60% of the population synchronously entered and progressed through the cell cycle. The transition from the resting state, signaled by increased RNA content, occurred about 12 to 24 hr after stimulation; S phase entry occurred at about 36 hr. Small, variable populations of cells appeared to be unresponsive to the stimuli, either because they were “preactivated” before in vitro stimulation or were already dying. The kinetics of appearance and accumulation of several cell cycle regulated/regulatory proteins were followed by immunoblotting. The proliferating cell nuclear antigen (PCNA) cyclin A and p33^cdk2 proteins were either absent or present in very low amounts in resting cells and first became detectable in increased amount beginning at about 24 hr after stimulation; increased p34^cdc2 protein was not detected until about 36 hr. Increased cellular content and phosphorylation of the p110^Rb protein was already obvious by 24 hr after stimulation. The effects of several immunosuppressive agents were examined using purified B cells. Both cyclosporin A and an FK506 analogue were shown to inhibit proliferation of B lymphocytes, at the low doses also inhibitory to T cells. © 1995 Wiley-Liss, Inc.     

Corticosteroid induction of Ig+Ia- B cells in vitro is mediated via interaction with the glucocorticoid cytoplasmic receptor

Flow microfluorometry was used to examine the effect of dexamethasone on the expression of surface Ia (sIa) on resting and activated murine B cells. Although dexamethasone resulted in a 50% reduction in sIa expression 12 h after injection, it was significantly less suppressive when injected together with B cell activators. In vitro dexamethasone, but not other related steroid hormones, induced a population of cells that were sIg+sIa-. A 20% reduction in the expression of sIa was noted by 4 h of culture with 10 nM dexamethasone, but maximal inhibition of 70% was not reached until 12 h of culture, and this degree of suppression persisted as long as dexamethasone remained in culture. When the dexamethasone was washed out after 8 h of culture, the maximal reduction was still noted at 12 h, but by 24 h there was re-expression of sIa toward base line levels, indicating it did not induce irreversible lethal alterations in the B cell. The inhibition of sIa expression correlated with a specific reduction in the quantity of messenger RNA for sIa as measured by Northern blot analysis, indicating that this is mediated at least in part by suppression of the steady state levels of Ia mRNA. The corticosteroid receptor antagonist RU486 was able to reverse the suppressive effects of dexamethasone on sIa expression, thus demonstrating that its effect is mediated specifically by binding to its intracellular receptor. Furthermore, when protein synthesis was inhibited during the short period of time that cells were preincubated with dexamethasone, minimal suppression of Ia expression was noted, suggesting that the dexamethasone may be stimulating a protein that has suppressive effects on MHC class II expression. The suppressive effects of dexamethasone in vitro were substantially reduced when B cells were simultaneously activated by stimuli that increase the expression of sIa. These data indicate that the suppressive effects of corticosteroids on immune response Ag are corticosteroid specific; are greater in resting than in activated B cells; are induced via the classical steroid mechanism of action, which is receptor mediated; and may result from the induction of an inhibitory protein that suppresses Ia mRNA.     

Modulation of Ia-like antigen expression and antigen-presenting activity of human monocytes by endotoxin and zymosan A

The environmental agents E. coli endotoxin and zymosan A modulated antigen-specific T cell proliferation in vitro, assessed by 3H-TdR uptake. In the continual presence of these agents, human mononuclear leukocyte responses to the antigens tuberculin PPD, Candida albicans, and mumps were significantly reduced. Treatment of adherent cell-depleted T cells with the agents did not affect their subsequent reactivity to soluble antigens in the presence of normal M phi. However, cultures consisting of pretreated M phi, normal T cells, and soluble antigen gave responses that were only 7 to 38% of control values, indicating that the function of the antigen-presenting cell, not the T cell, was inhibited. This effect was observed only when treatment with endotoxin or zymosan A preceded antigen stimulation by at least 24 hr, suggesting that a gradual inhibition of antigen presentation had occurred. When various ratios of normal antigen-pulsed and agent-treated M phi were cultured with normal T cells, antigen-specific responses were not significantly different from control cultures; this indicated that M phi-mediated suppression was not involved. It did not appear that the inhibition was due to enhanced antigen degradation by the treated M phi because responses were not reconstituted in the presence of excess antigen. After endotoxin or zymosan A treatment of the M phi population the proportion of Ia+ cells was reduced significantly, and surface expression of Ia antigen correlated with the ability of the cell population to present antigens to immune T cells. This suggested that endotoxin and zymosan A induce a loss of surface Ia antigen on antigen-presenting cells that inhibits immune T cell activation.     

T lymphocyte heterogeneity in the rat. III. Autoreactive T cells are activated by B cells

Evidence has been presented to show that CD4+ autoreactive T cell lines (ATs)2 in the rat require periodic stimulation with syngeneic spleen cells for in vitro proliferation. This proliferation can be blocked by treatment of the stimulator (spleen) cells with mAb to Ia antigens. Although ATs are Ia+ and can activate the allogeneic MLR, they fail to be autostimulatory. Fractionation of the spleen cells revealed that ATs can be stimulated with B cells and not by macrophages, although the latter were efficient in several accessory cell functions, including antigen presentation, lectin-dependent T cell activation and allogenic MLR response. Moreover, B cells proliferated and differentiated in response to AT cells. These data are compatible with a model in which ATs respond to hitherto undetermined B cell membrane antigen(s) in association with MHC class II antigens. These results may have important implications in understanding autoimmune responses.