Detection of human B cells and chronic myelocytic leukemic cells by rosette formation with sheep erythrocytes and fresh human sera.

A new method of detecting the C3b receptor is reported. A particular merit of this method is that anti-RBC rabbit antiserum is not required. Rosettes were formed with human B lymphocytes, B lymphoblasts and granulocytes, using sheep erythrocytes (SRBC) sensitized with fresh human serum (FHS). T lymphocytes and T lymphoblasts did not form rosettes. The percentage of cells forming rosettes with this method approximated the percentage of rosettes formed with EACm. However, FHS coated SRBC did not react with most cells of B cell type chronic lymphocytic leukemia (CLL), whereas EACm rosette formations showed a definite reaction. On the other hand, 34--58% of cells of chronic myelocytic leukemia (CML) bound with the indicator red cells. SRBC sensitized with fresh rabbit or guinea pig serum formed rosettes with PBL, tonsil cells, B lymphoblasts and granulocytes. Complement and IgM antibody were required for this reaction, as in EAC rosette formation.     

Studies of the sheep red blood cell receptor using anti-lymphocyte antibodies

Human thymus derived lymphocytes (T cells) interact with sheep red blood cells (SRBC) to form rosettes. We wanted to determine whether the lymphocyte's receptor for SRBC is associated with serologically detectable cell surface antigens. Antisera were prepared by immunizing horses with either fresh human thymus (ATG) or with B lymphocytes from an established lymphoid cell line in culture (ALG). ATG, ALG or Concanavalin A (Con A) were added to lymphocyte preparations to determine their effect on rosetting. The results showed that ATG inhibited rosettes in a dose dependent manner. In contrast, both the Con A and ALG had no effect. By immunofluorescence, Con A and ALG staining cells were able to form rosettes. ATG staining cells were unable to form rosettes. Removal of the ATG receptor by capping could not restore the rosette forming capacity suggesting that inhibition was not due to steric hindrance. We conclude that antibody directed against T cells but not B cells binds to surface antigens which appear to be identical with or in close proximity to the specific SRBC receptor.     

Activated T lymphocytes within human solid tumors

Summary The majority of lymphocytes separated from tumor cell suspensions were T cells. Conjugates of T lymphocytes and tumor cells were often seen. Variable numbers of T cells exhibited signs of activation such as the ability to form stable E rosettes and attachment to normal and malignant cells (a phenomenon designated natural attachment: NA). A proportion of T cells activated in vitro by allogeneic stimulation regularly exhibit these properties. The T cell-tumor conjugates in the suspensions may represent the NA phenomenon, but they could also be the product of T cells that adhere on the basis of specific recognition of cell surface antigens.Abbreviations BBS balanced salt solution - E rosettes rosettes formed with sheep erythrocytes - EA rosettes rosettes formed with ox erythrocytes coated with anti-ox IgG - FCS fetal calf serum - MLC mixed lymphocyte cultures - NA natural attachment - PBL peripheral blood lymphocytes - SRBC sheep erythrocytes - T lymphocytes thymusderived lymphocytes     

EA rosette forming lymphoid cells: distribution as to cell types and organs from chickens of different developmental stages.

The interaction of chicken spleen cells with sheep erythrocytes coated with chicken antibody (EA complexes) was studied using a rosette assay. The results reported in this paper indicate that subpopulations of chicken lymphocytes, monocytes, and heterophils have a receptor for EA. The formation of rosettes between chicken lymphoid cells and sheep erythrocytes (SRBC) was dependent upon the concentration of antibody used to sensitize the SRBC. In a developmental study of rosette-forming lymphocytes (RFL), the bursa was the first site of appearance of large numbers of RFL. The percentage of RFL in the bursa reached a peak at 17 days of embryonic life, and declined to a low by hatching. The percentage of RFL in the spleen, however, began to increase at the time of hatching and by 6 weeks of age the spleen far surpassed the bursa in percentage RFL. At no age were significant numbers of RFL detected in the thymus.     

Characterization of human T lymphocytes that express the C3b receptor

The presence of the C3b receptor (C3bR) on human peripheral blood T lymphocytes was recognized by the capacity of rabbit F(ab')2 anti-C3bR and tetramethylrhodamine isothiocyanate (TRITC)-conjugated goat F(ab')2 anti-rabbit F(ab')2 to stain 14.5 +/- 3.7% (mean +/- SEM; n = 5) of lymphocytes forming rosettes with sheep erythrocytes (E). The F(ab')2 anti-C3bR also blocked the capacity of peripheral blood lymphocytes stained with OKT11 to form rosettes with bovine E bearing C3b and immunoprecipitated a single membrane protein having a m.w. of approximately 250,000 from detergent lysates of 125I-labeled, purified T cells. Measurement by fluorescent flow cytometry of the quantitative expression of the C3bR indicated that T cells had slightly more antigenic sites/cell than did E and approximately 10-fold fewer sites than were present on B cells. The surface constituents of the peripheral blood T cells expressing the C3bR were assessed in an assay that employed simultaneously three markers: rosette formation with sheep E, TRITC staining with anti-C3bR and fluorescein isothiocyanate (FITC)-staining with a panel of monoclonal antibodies or with aggregated IgG. Among lymphocytes forming rosettes with sheep E and expressing the C3bR, 99.6 +/- 0.4%, 65.0 +/- 5.8%, 17.2 +/- 6.2%, and 15.3 +/- 5.0% of the cells expressed antigens detected by OKT3, OKT4, OKT8, and OKM1 monoclonal antibodies, respectively. Ninety-seven per cent of the C3bR-bearing T cells were also capable of specifically binding aggregated IgG, indicating the presence of Fc receptors for IgG (Fc gamma R) on these cells. The T cells expressing the C3bR had large nuclei, thin rims of basophilic cytoplasm and no azurophilic granules. Thus, the C3bR is present on some T cells, all of which have a typical lymphocyte morphology, the T3 antigen and the Fc gamma R.     

A study of the variable heavy chain (VH) region of membrane-bound Ig on human chronic leukemic lymphocytes.

Lymphocytes from 20 patients with chronic lymphocytic leukemia (CLL) were studied for membrane staining by direct immunofluorescence by employing anti-F(ab')2, anti-VHI, anti-VHII, anti-VHIII subgroup-specific antisera, as well as light chain-specific antisera. Some lymphocyte preparations were also studied in indirect immunofluorescence with an antiserum raised against a fragment (VH) corresponding to the variable region of the heavy chain of a human IgG3 myeloma protein (Kup). Lymphocytes from each CLL patient demonstrated a restriction of VH subgroups expressed on the cell membrane; six were restricted to the VHI subgroup, seven to VHII, and seven to the VHIII subgroup. This restriction gave further evidence for monoclonality of the membrane-bound Ig and the leukemic cell proliferation. Antiserum to the VH fragment stained closely similar percentages of CLL lymphocytes to that obtained with anti-F(ab')2 antiserum. Furthermore, double staining revealed that the same cells were stained with anti-VH antiserum as were stained with anti-F(ab')2 antiserum, i.e., only the B lymphocytes.     

Inhibition of human T lymphocyte E rosette formation by neutrophils and hydrogen peroxide. Differential sensitivity between helper and suppressor T lymphocytes

Co-incubation of human mononuclear cells with small numbers of autologous polymorphonuclear leukocytes resulted in a ratio-dependent inhibition of T lymphocyte rosette formation with sheep erythrocytes (SRBC). Inhibition by polymorphonuclear leukocytes was reversed with catalase, implicating H2O2 or associated products as the suppressive agent(s). Exposing T lymphocytes directly to micromolar concentrations of H2O2 also inhibited subsequent rosette formation. Inhibition was dose-dependent between 40 and 320 microM H2O2 and was not due to cytotoxicity at those H2O2 concentrations. Kinetic studies demonstrated that after exposing T lymphocytes to H2O2 a proportion of cells appeared to be relatively resistant in that they retained their ability to form E rosettes. T cell phenotype analysis of these cells showed that, in contrast to untreated T cells, H2O2-treated T rosette-forming cells were almost exclusively of the helper/inducer phenotype. Analysis with the monoclonal antibody 4B4 revealed that H2O2-resistant T rosette-forming cells contained significantly fewer 4B4-positive cells than predicted for the T helper population, indicating that H2O2-resistant T cells might be a subset of helper/inducer T lymphocytes. The interaction between H2O2 and T cells was rapid but did not lead to loss of Leu-5b binding sites. Preliminary functional analysis indicates that interleukin 2 production and phytohemagglutinin-induced proliferation by the relatively H2O2-resistant T cells is similar to untreated T cells. In contrast, H2O2-treated T cells which lost their ability to form E rosettes produced undetectable levels of interleukin 2 and proliferated poorly in response to phytohemagglutinin. Finally, mononuclear cells pretreated with H2O2 and subsequently stimulated with mitogens demonstrated a preferential expansion of the T helper population with concomitant loss of T suppressors. Our results show that, although neutrophil-released H2O2 inhibits effective interactions between SRBC and T lymphocyte sheep erythrocyte receptors, there appears to be a population of T helper cells which is relatively resistant to H2O2 both in terms of SRBC rosette formation and response to mitogens. These data suggest that at sites of inflammation phagocyte-released H2O2 could exert immunoregulatory effects on T cells by altering T cell subset survival and allowing the function of a particular lymphocyte population to predominate.     

The significance of varying SRBC/lymphocyte ratio in T cell rosette formation.

The incubation ratio of sheep red blood cells (SRBC) to lymphocytes is a critical factor in rosette formation, whereas the length of time SRBC and lymphocytes are incubated together does not significantly affect the percentage of lymphocytes forming rosettes. The graph obtained by plotting percentage of rosette formation against the ratio of SRBC to lymphocytes is similar to that resulting from the formation of bimolecular complexes. If rosette formation is analogous to formation of bimolecular complexes, maximal rosette formation occurs when the system is saturated, i.e., with excess SRBC, and is a measure of the total capacity of a lymphocyte population to form rosettes. In addition, the percentage of rosette formation observed at a limiting SRBC/lymphocyte ratio gives an indication of the avidity of the lymphocytes for SRBC. This interpretation may provide an explanation for the difference between the "active" and "total" rosettes. When the log of the SRBC/lymphocyte ratio is plotted against percentage of rosette formation, a straight line is obtained, suggesting that within a given normal lymphocyte sample, T cell subsets with different avidities are not detected by rosette formation at different SRBC/lymphocyte ratios.     

E rosette formation at 37°:A property of mitogen-stimulated human peripheral blood lymphocytes

Peripheral blood lymphocytes from healthy humans formed stable E rosettes with sheep erythrocytes (SRBC) at 37°C after culture with phytohemagglutinin or the divalent cation ionophore A23187. Cells manifesting this phenomenon exhibited “blast” morphology, appeared by 16 hr of culture, increased dramatically in percentage and absolute number by 62 hr, and persisted in large numbers for the duration of culture (182 hr). Unstimulated lymphocytes formed rosettes at 4°C but not at 37°C. Increased “stickiness” due to surface-bound lectin mitogen was not the cause of rosette formation at 37°C.Formation of E rosettes at 37°C has previously been considered a property of lymphocytes less differentiated than the circulating T cell (e.g., thymocytes, leukemic lymphoblasts). The present findings indicate that this property can be “reexpressed” during blastogenesis in culture.This observation also demonstrates technical problems associated with the use of SRBC to quantitate lymphocytes with complement receptors (B cells) by the EAC rosette assay in culture. False positives resulted from 37°C E rosette formation, but this was overcome by replacing the SRBC with guinea pig erythrocytes in the EAC assay.     

Lymphocyte populations of Callithrix jacchus marmosets.

A lymphocyte population of common marmosets (Callithrix jacchus) was identified by rosette formation with African green monkey erythrocytes; the rosette-forming cells appeared to be T lymphocytes, as approximately 62% of circulating lymphocytes and 85% of thymus cells formed rosettes with African green monkey erythrocytes. In addition, common marmoset lymphoid cells carrying T-lymphotropic Herpesvirus saimiri or Herpesvirus ateles formed rosettes with African green monkey erythrocytes and treatment of common marmoset circulating lymphocytes with an anti-T cell serum and complement (C′) eliminated rosette-forming cells. Common marmoset T lymphocytes apparently carry a surface receptor for African green monkey erythrocytes, but unlike humans and other closely related nonhuman primates, T lymphocytes of common marmosets fail to form rosettes with sheep erythrocytes.     

Regulation of the cytotoxic effect of human ‘normal killer cells’ on tumor cell lines by neuraminidase-treated T-lymphocytes

Summary Subpopulations of peripheral blood lymhocytes (PBL) from healthy individuals were separated according to their capacity to form various rosettes and tested for their cytotoxic activity on cell lines of urinary bladder and breast carcinomas. The subpopulation exerting the highest natural cytotoxic activity was characterized by the presence of cell surface Fc-receptors and by the lack of receptors for sheep red blood cells and for C'3 on their surface. Treatment with vibrio cholera neuraminidase (VCN) increased the cytotoxicity of unseparated PBL to a level twice as high as that of untreated PBL. The attachment of T-lymphocytes to tumor monolayers was increased several fold after VCN-treatment, while the attachment of other lymphocyte subpopulations was not. Evidence is presented that the augmentation of the cytotoxicity of PBL following VCN-treatment results from the interaction of VCN-treated T-lymphocytes, attached to target cells, with normal killer cells. It is suggested that augmentation of the activity of killer cells by T-lymphocytes may play a role in antitumor defense mechanisms.Abbreviations CMC Cell-mediated cytolysis - E-rosettes Rosettes formed with sheep red blood cells - EA-rosettes Rosettes formed with red blood cells coated with antibody - EAC'-rosettes Rosettes formed with red blood cells coated with antibody and complement - FCS Heat inactivated fetal calf serum - PBL Peripheral blood lymphocytes - RBC Red blood cells - RF-TAL E-rosette forming, target-attached lymphocytes - SRBC Sheep red blood cells - VCN Vibrio cholera neuraminidase     

Immunologic dysfunction during viral oncogenesis. I. Nonspecific immunosuppression caused by malignant rabbit fibroma virus

Malignant rabbit fibroma virus (MV) is a potent oncogenic poxvirus that produces a rapidly progressive syndrome of disseminated myxosarcoma, immunosuppression, and fatal gram-negative infection. MV is probably a recombinant between Shope fibroma virus (SFV) and rabbit myxoma virus, and is capable of preventing or aborting the in vitro proliferative responses of rabbit lymphocytes to B and T lymphocyte mitogens. Proliferative responses to sheep erythrocytes (SRBC) are similarly affected, although MV does not alter ongoing antibody responses to SRBC. Splenic lymphocytes from MV tumor-bearing rabbits suppress antibody and proliferative responses to SRBC when added to lymphocytes from SRBC-primed rabbits. Finally, lysates of cultured splenic lymphocytes from rabbits given MV suppress both proliferative and antibody-forming responses to SRBC. When MV is removed from these lysates by UV inactivation or by centrifugation, the suppressive activity remains. We therefore conclude that MV induces immunologic unresponsiveness in rabbits by at least two mechanisms. First, a direct suppressive effect of added virus on in vitro lymphocyte proliferation is seen. There is no effect in this situation if an antibody response is already in progress. Second, spleen cells exposed to MV in vivo produce one or more soluble factors capable of suppressing both proliferative and antibody responses of normal lymphocytes.     

Human lymphocyte subpopulations: giant SRBC rosettes.

Human thymus-derived lymphocytes have the ability to form rosettes with sheep red blood cells (SRBC) in vitro. In the investigation of rosettes of peripheral blood lymphocytes of 10 normal subjects, the number of SRBC adhering to the lymphocyte in each of 100 rosettes was assessed. The percentage of rosettes with SRBC greater than or equal to 36 per rosette was only 1.2 +/- 0.5. These were defined as giant SRBC rosettes. Peripheral blood lymphocytes were stimulated in vitro by four mitogens: sodium periodate, neuraminidase plus galactose oxidase, pokeweed mitogen, and concanavalin A. The lymphocytes were then cultured at 37 degrees C. The giant rosette-forming lymphocytes became significantly increased 4 to 24 hr after stimulation, prior to the appearance of lymphoblasts or increased incorporation of tritiated thymidine. The giant rosettes were not caused by the hemagglutinating properties of pokeweed mitogen and concanavalin A that were adsorbed on the lymphocyte surfaces. This was shown by the fact that, on removal of the receptors by trypsinization, they were regenerated on culture in vitro in the absence of the mitogens. It was concluded that giant SRBC rosettes constituted a marker for some of the activated lymphocytes. Their appearance was independent of the increase in size of the cells or of DNA synthesis. These receptors were intrinsic to lymphocytes and not caused by mitogens adsorbed on their surfaces.     

Morphological differences in the interactions between human mononuclear cells and coated or uncoated sheep red blood cells

Summary Enriched preparations of E, EA and EAC rosettes formed by human peripheral blood mononuclear cells were freeze-etched and examined electron-microscopically. In E rosettes only lymphocytes were involved, whereas in EA and EAC rosettes lymphocytes and mononuclear phagocytes participated as rosette-forming cells. In EA and EAC rosettes, cytoplasmic extensions of the rosette forming cell were seen to penetrate the sheep red blood cell, whereas E rosettes showed a broad zone of adherence without penetration. None of the three types of rosettes showed an interspace between the membranes. Unlike E rosettes, EA and EAC rosettes showed polarity in the adherence of sheep red blood cells. These observations made by freeze-etch electron microscopy indicate distinct morphological differences between rosettes formed with coated or uncoated erythrocytes.The authors wish to thank Prof. Dr. A. Cats, Dr. P.C.J. van Breda Vriesman and Dr. J.C.H. de Man for helpful discussion and criticism; the assistance of Miss R. Kleinjan and Mrs. A.C. Scheurkogel-van Efferen is gratefully acknowledged. This work was supported in part by a grant of the Praeventiefonds     

Human eosinophils express CR1 and CR3 complement receptors for cleavage fragments of C3

The functional and antigenic characteristics of C3 receptors expressed on human eosinophils were investigated using rosette assays with sheep erythrocytes coated with C3 fragments and flow cytometric analysis of cells stained with anti-receptor antibodies. Purified peripheral blood eosinophils from 13 patients with hypereosinophilia expressed CR1 antigens. In 8 patients, a mean of 14 + 9.5% eosinophils formed C3b-dependent rosettes that were inhibited by F(ab')2 anti-CR1 antibodies. This number increased to 33% following stimulation with leukotriene B4 (LTB4) (10(-7) M). Similar numbers of C3b rosettes were formed by hypodense and normodense eosinophils. Eosinophils from 2 patients from this group expressed 20,000 125I-labeled monoclonal anti-CR1 antibody binding sites/cell. In another group of patients, 55 +/- 9% eosinophils spontaneously formed C3b-dependent rosettes that could not be enhanced by LTB4. In all patients, a mean of 16 +/- 9% eosinophils formed cation-dependent rosettes with C3bi-bearing intermediates that were inhibited by anti-CR3 antibody OKM1. All eosinophils stained with monoclonal antibodies against the alpha chain of CR3. There was no C3d-dependent rosette formation with eosinophils and no eosinophils stained with monoclonal anti-CR2 antibody. Thus, human eosinophils express CR1 and CR3. Since CR3 is required for the adhesion of granulocytes to surfaces and antibody-dependent cellular cytotoxicity of neutrophils, the interaction of C3 fragments with CR3 and CR1 on eosinophils may be of importance in eosinophil-mediated damage of opsonized targets.     

The ligand of the erythrocyte receptor of T lymphocytes: expression on white blood cells and possible involvement in T cell activation

We have recently described a monoclonal antibody (mAb) to sheep erythrocytes, termed L180/1, that blocks the formation of E rosettes between human or sheep T lymphocytes and sheep red blood cells. The cell surface glycoprotein (GP) of 42,000 apparent m.w. recognized by mAb L180/1 was given the preliminary name T11 target structure or T11TS. In the present report, it is shown that T11TS is also expressed on sheep white blood cells, notably on activated T lymphocytes, that are shown to actively synthesize this cell surface GP. In addition, the mixed lymphocyte reaction between outbred sheep is inhibited by mAb L180/1 at an early stage of the response. Together with the known involvement of the E receptor in T lymphocyte activation, these results are taken to suggest that T11 and T11TS are complementary cell interaction molecules involved in regulating T cell proliferation.     

Numbers of rosette formine cells in human peripheral blood.

Thymus-derived (T-cell) and “bursal” derived (B-cell) lymphocytes in human peripheral blood were quantitated by assaying percentages of cells forming erythrocyte rosettes. T-cell rosettes were formed with neuraminidase treated sheep erythrocytes. B-cell rosettes were formed with complement coated sheep erythrocytes. Large differences in the percentages of T-rosette forming cells were noted depending on the method used to assay these cells. When rosette forming cells (RFC) and non-RFC were counted concurrently the percentage of T-cell rosettes were 53–75% whereas methods involving the separate counting of RFC and total cells gave T-cell RFC percentages of 23–40%. These differences were due to the “co-rosetting” of non-RFC into the T-cell rosette clusters. This occurred because of the gentleness required to resuspend the fragile T-cell rosettes. “Co-rosetting” was demonstrated by forming stable complement receptor rosettes with complement-coated human erythrocytes and resuspending them either gently or vigorously. Significantly higher percentages of rosettes were noted with gentle cell suspension than with vigorous resuspension. The percentages of rosette forming T-cells in human peripheral blood are therefore lower than previously estimated.     

Separate Thymus Dependent and Thymus Independent Antibody Forming Cell Precursors

COOPERATION between bone marrow-derived (B) and thymus-derived (T) lymphocytes in antibody formation in mice is well established¹ and with sheep red blood cells (SRBC) as the antigen the detectable antibody-forming cells are of marrow and not thymus origin². Gershon and Kondo have recently suggested that the T cells requiring B cell cooperation for antibody production may also require it for tolerance induction, but that other B cells do not require T cell cooperation for either process³.     

Morphometric ultrastructural evaluation of human peripheral blood T lymphocyte subpopulations isolated on the basis of their affinity for sheep red blood cells

The present investigation were undertaken to compare on the basis of ultrastructural morphometric analysis human T lymphocyte subfractions forming rosettes with sheep red blood cells (SRBC). The following T lymphocyte subfractions were obtained: ARFC (active rosettes), T1RFC (rosettes after 1 h at 4 degrees C) and T2RFC (rosettes after 2 h at 4 degrees C). Analysis of the mean cell and nuclei volumes of lymphocyte subfractions led to the separation of two cell groups differing in volume in each donor: a cell group consisting of large cells (T1RFC) and group of small cells (ARFC and T2RFC).     

Distinctive functional properties of human blood L lymphocytes: a comparison with T lymphocytes, B lymphocytes, and monocytes.

Human blood lymphocytes with high affinity Fc receptors have been operationally named L lymphocytes because of membrane-labile IgG markers. L lymphocytes lack membrane-incorporated immunoglobulin and do not form rosettes with sheep red blood cells coated with IgM antibody and mouse complement. These lymphocytes are capable of binding IgG in normal human serum at 4 degrees C and will form rosettes with human lymphocytes coated with Ripley IgG. In this study, functional in vitro properties of isolated L lymphocytes were compared with T lymphocytes, B lymphocytes, and monocytes. To obtain these mononuclear populations, first, plastic adherent monocytes were harvested. T lymphocytes were then isolated by centrifugation of E rosette-forming cells, and other rosetting techniques were employed to isolate L and B lymphocytes by negative selection. The functional properties of L lumphocytes were completely unlike those of T cells, B cells, or monocytes. L lymphocytes did not proliferate in response to mitogens, soluble antigens, or cell surface antigens. Moreover, this population could not replace monocytes in helping T lymphocytes respond to concanavalin A and pokeweed mitogen. Once T cells were supplemented with monocytes, however, the addition of L lymphocytes to the culture greatly enhanced the T lymphocytes proliferative response to phytohemagglutinin, concanavalinA, purified protein derivative (PPD), and streptokinase/streptodornase. L lymphocytes were not a subset of B cells. They did not spontaneously develop surface Ig in culture, and pokeweek mitogen could not induce them to transform and generate cytoplasmic Ig detectable by immunofluorescence. Mixtures of B cells and T cells responded to pokeweed mitogen better than do T cells alone. In contrast, enhanced reactivity with L and T cell combinations was not observed. Another sharp difference between these two populations was the stimulator capacity of each in mixed lymphocyte culture. When B and L lymphocytes were carefully monocyte-depleted, only B cells were effective stimulators of autologous and allogeneic lymphocytes. In comparison with T cells, B cells, and monocytes, L lymphocytes were the only effective killers of human blood lymphocytes sensitized with IgG. L lymphocytes, then, have cytotoxic potential, but cannot proliferate in response to various stimulants or become antibody-producing cells. These findings suggest that L lymphocytes comprise a third lymphocyte population.