Human lymphocyte receptor movement induced by sheep erythrocyte binding: effect of temperature and neuraminidase treatment

The formation of sheep red blood cells (SRBC) rosettes by human lymphocytes was promoted by incubation at 4 °C and by treatment of the lymphocytes or SRBC by neuraminidase. On incubating the untreated SRBC rosettes at 37 °C, the rosettes dissociated by capping in which rings were converted into horseshoes and then caps. This capping was inhibited by incubation of the rosettes at 4 °C and partially by treatment of the cells with neuraminidase. During rosette formation, the proportion of caps decreased progressively during 4 °C incubation. This decrease of capping was also promoted by neuraminidase treatment. We concluded that the main reason why 4 °C and neuraminidase treatment facilitated rosette formation was by inhibition of capping.     

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.     

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.     

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.     

Carbohydrate specificity of T-cell cytophilic chicken anti-SRBC IgM antibodies.

Fixation of passively sensitized lymphocytes by formaldehyde resulted in amplified erythrocyte rosette formation. The cytophilic anti-SRBC antibodies were of the IgM class and they attached selectively to thymocytes and T lymphocytes. Anti-SRBC sera from approximately 30% of immunized chickens gave rosette counts between 500–1500 per 10⁴ cells whereas the remainder gave values considerably lower. The onset and peak of the cytophilic IgM response were reached later than that of IgM haemagglutinating antibodies and there was little correlation between the count of cytophilic rosettes and haemagglutinjn titres in individual chickens. On the basis of competitive inhibition of rosette formation by a hog blood group substance it is suggested that the cytophilic antibodies have binding site specificity for a saccharide on the surface of SRBC.     

树鼩(Tupaia belangeri)淋巴细胞的自体花结

参与人自体花结(A花结)形成的分子(如CD2/LFA-3),与免疫细胞的粘附和激活有关。我们曾发现,人和猴淋巴细胞表面的树鼩红细胞(TRBC)受体不同于绵羊红细胞(SRBC)受体(CD2),可能是一种新的白细胞分化抗原。花结试验表明,树鼩的外周血淋巴细胞(TPBL)和胸腺细胞都能形成A花结,结花率分别为20.9％和11.1％;而绵羊红细胞花结(E花结)形成率分别是20.9％和1.1％。以四种单克隆抗体(McAb)(Leu 5,0-275,AICD2.1和E2 McAb)进行树鼩A花结和E花结的抑制与抗原调变试验,结果表明,这些抗体对树鼩的A花结都没有明显的抑制或调变作用,但对E花结的抑制及调变作用明显。说明TPBL表面的TRBC受体不同于SRBC受体,与CD2/LFA-3及E2分子无关。因此,TPBL的A花结与E花结形成机制不同。     

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.     

Cross-reactivity between human and murine lymphocyte antigens: III. Reactivity of H-2 allo- and xenoantisera with human lymphoid cells

H-2 alloantisera and antimouse lymphocyte xenoantisera react with 14%–100% of human lymphocytes from a panel of at least 80 unrelated people. Population and family studies did not reveal HL-A specificity of such lymphocytotoxic antibodies but indicated that the antibodies are directed against polymorphic antigenic determinants inherited in association with HL-A antigens. H-2 allo- and xenoantisera absorbed with human lymphoid cells and a panel of platelets bearing all the known HL-A specificities were still cytolytic when tested against murine lymphocytes, suggesting that only a small proportion of the heterogeneous population of H-2 antibodies react with human lymphocytes. On the other hand, HL-A alloantisera could be absorbed by lymphocytes from certain murine strains. These results suggest that the crossreactivity between human and murine lymphocytes is caused by antigens common to several HL-A (or H-2) types or by antigens linked to HL-A but not identical with them.     

Delineation of the development of T lymphocytes from leukemic null lymphocytes upon induction by conditioned medium

Null lymphocytes, lacking B- and T-lymphocyte markers, were isolated from PBL of patients with acute lymphocytic leukemia. Upon culture in the presence of medium produced from PHA-stimulated allogeneic lymphocytes, induction of these cells to T lymphocytes occurred. Within 18 hr, they acquired the capacity to form SRBC rosettes and bind complement components, IgG or IgM. This differentiation, as supported by cell cycle kinetic analysis, was accompanied by lymphocyte activation, inferable from warm SRBC rosetting. Capping of these rosettes was identified as indicative of early T lymphocytes. During T-lymphocyte development subclasses bearing complement receptors, followed by IgG and finally IgM receptors appeared. The emergence of subclasses, functionally expressed by a gain in MLC responsiveness and stimulatory capacity reflected T-lymphocyte maturation. Simultaneous with the later decrease of the subclasses was a decrease in MLC reactivity. This elucidation of T-lymphocyte development may help in dissection of the lymphoid system.     

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.     

Marmoset red blood cell receptor for membrane-associated complement components is not related to human CR1: partial characterization of the C3-binding proteins responsible for the spontaneous rosette formation between marmoset red blood cells and human leukocytes

Cells from all the human B-lymphoblastoid cell lines tested and most human monocytes form rosettes with marmoset red blood cells (MaRBC). Because previous reports suggested the involvement of complement components in this phenomenon, the mechanism of rosette formation and the eventual similarities between the MaRBC receptor and the CR1 receptor present on human erythrocytes have been analyzed herein. The binding of MaRBC to human leukocytes strongly differs from the immune adherence phenomenon: rabbit anti-human CR1 did not react with MaRBC and the MaRBC receptor-binding activity is Ca2+-dependent. Rosette formation required intact energy metabolism and cytoskeleton integrity of leukocytes. Our attempts to purify the receptor from MaRBC membranes revealed the absence of CR1. Nevertheless, C3-binding proteins were isolated by selective desorption by Sepharose iC3 column chromatography. A three-band pattern was observed under reduced conditions with 74,000, 70,000, and 53,000 molecular weights. It was not possible to further separate these components. This protein complex inhibited the rosette phenomenon between MaRBC and both Raji and U-937 cells, exhibited a very poor cofactor activity, and had no decay-accelerating activity toward the classical C3 convertase. This material did not cross-react with antibodies directed to human proteins. These results showed that erythrocytes from new world monkeys do not express a receptor analogous to the human CR1, but expressed C3-binding protein with low cofactor activity that could recognize membrane-associated complement components.     

Human T and B lymphocyte rosette tests: Effect of enzymatic modification of sheep erythrocytes (E) and the specificity of neuraminidase-treated E

Sheep erythrocytes (E) were treated with papain or neuraminidase to evaluate what effect these enzymes would have on the E rosette test for human T lymphocytes. Few or no rosettes were detected with sheep erythrocytes treated with papain (E_P). Sensitization of E_P with rabbit antibody and mouse complement resulted in a rosette indicator (E_PAC) which could be used to detect peripheral blood complement receptor lymphocytes (CRL) and thymocyte CRL without having to perform the rosette assay at 37 °C. Neuraminidase treatment of E (E_N) enabled the detection of approximately 20% more rosette-forming cells (RFC) in human peripheral blood lymphocyte (PBL) suspensions compared to untreated E. Rosette studies on a patient with severe combined immunodeficiency disease and on human lymphoblastoid cell lines showed that the additional rosettes detected with E_N were T lymphocytes.     

Membrane receptors of mouse leukocytes. I. Two types of complement receptors for different regions of C3

Mouse leukocytes were studied for membrane receptors for the third C component by rosette formation with C coated erythrocytes (EAC). Methods were devised for the preparation of EAC complexes containing either mouse C3b or mouse C3d. EAC 1-3dmo were prepared from EA treated with whole mouse serum while EAC 1-3bmo were produced from EAC 142hu treated with whole mouse serum containing sodium suramin. The specificity of the EAC complexes for mouse leukocytes was confirmed by inhibition experiments using fluid phase human C3d. Low concentrations of fluid phase human C3d inhibited EAC1-3dmo rosettes but failed to inhibit EAC 1-3bmo rosettes. Eight-fold higher concentrations of fluid phase C3d caused partial inhibition of EAC1-3bmo rosette formation with lymphocytes, but not with other types of murine leukocytes. Thus mouse leukocytes apparently contain the same two types of C receptors as do human and guinea pig leukocytes. Mouse CR1 is specific for a non-C3d region of C3b, (possibly analogous to human C3c) whereas mouse CR2 is specific for both C3d and the C3d region of C3b.     

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.     

Fluctuation of Antigen Binding Activity during the Cell Cycle in the Synchronized Population of the Murine T Hybridoma Cell Line

The murine T cell hybridoma line which specifically binds antigen (ovalbumin) was established using a cell fusion technique with Sendai virus. Regional lymph node cells from ovalbumin (OVA) immunized C57BL/6 mice were fused with thymidine kinase deficient variant cells of the EL-4 cell line (originating from a thymoma of a C57BL/6 mouse). Approximately one hundred cell lines were established and the antigen binding activity was determined by rosette formation with OVA coated sheep red blood cells (SRBC). One hybridoma cell line, MMH-77, could form rosettes and this formation was specifically inhibited by the addition of free OVA. The ability of the cell line to form rosettes varied from one stage of the cell cycle to the other with the maximum ability in the S phase.     

Binding of fluid-phase complement components C3 and C3b to human lymphocytes.

It is known that a population of B-lymphocytes has receptors for the third component of complement, C3, and that these lymphocytes may be identified by their ability to form rosettes with sheep erythrocytes coated with covalently bound fragments of complement component C3. Human tonsil lymphocytes, enriched for B-cells, form rosettes with sheep erythrocytes coated with antibody and complement components C1, C4b and C3b (EAC143b cells). Fluid-phase C3 will inhibit rosette formation between EAC143b and human tonsil lymphocytes over the same concentration range as fluid-phase C3b. C3 is not cleaved to C3b during incubation with lymphocytes or with lymphocytes and EAC143b cells. Fluid-phase 125I-labelled C3 and 125I-labelled C3b bind to lymphocytes in a specific manner. The characteristics of binding of both radioiodinated C3 and radioiodinated C3b are very similar, but the binding oc C3 is again not a result of cleavage to C3b. Salicylhydroxamic acid does not inhibit binding of 125I-labelled C3 to tonsil lymphocytes at concentrations that completely inhibit binding of 125I-labelled C3 to EAC142 cells via the nascent binding site of C3b. It is concluded that C3 and C3b share a common feature involved in binding to lymphocytes bearing receptors for the third component of complement.     

Mapping of the region of complement receptor (CR) 1 required for Plasmodium falciparum rosetting and demonstration of the importance of CR1 in rosetting in field isolates

The malaria parasite Plasmodium falciparum induces a number of novel adhesion properties in the erythrocytes that it infects. One of these properties, the ability of infected erythrocytes to bind uninfected erythrocytes to form rosettes, is associated with severe malaria and may play a direct role in the pathogenesis of disease. Previous work has shown that erythrocytes deficient in complement receptor (CR) 1 (CR1, CD35; C3b/C4b receptor) have greatly reduced rosetting capacity, indicating an essential role for CR1 in rosette formation. Using deletion mutants and mAbs, we have localized the region of CR1 required for the formation of P. falciparum rosettes to the area of long homologous repeat regions B and C that also acts as the binding site for the activated complement component C3b. This result raises the possibility that C3b could be an intermediary in rosetting, bridging between the infected erythrocyte and CR1. We were able to exclude this hypothesis, however, as parasites grown in C3-deficient human serum formed rosettes normally. We have also shown in this report that rosettes can be reversed by mAb J3B11 that recognizes the C3b binding site of CR1. This rosette-reversing activity was demonstrated in a range of laboratory-adapted parasite strains and field isolates from Kenya and Malawi. Thus, we have mapped the region of CR1 required for rosetting and demonstrated that the CR1-dependent rosetting mechanism occurs commonly in P. falciparum isolates, and could therefore be a potential target for future therapeutic interventions to treat severe malaria.     

Natural cytotoxic reactivity of human lymphocytes against a myeloid cell line: characterization of effector cells.

Using a series of techniques to identify and deplete various peripheral blood lymphocyte subpopulations, we studied the cytotoxic reactivity of normal individuals against the myeloid cell line K-562 in a 4-hr 51chromium-release assay. Depletion of lymphocytes bearing complement receptors had a variable, usually negligible effect on cytotoxicity. In contrast, depletion of lymphocytes bearing Fc receptors abrogated target cell lysis. Separation of lymphocytes with high-affinity binding of sheep red blood cells (SRBC) evidenced by rosette formation at 29 degrees C yielded a population of rosette-forming cells containing few cytotoxic cells, whereas separation of total E-RFC under optimal rosetting conditions produced a rosette fraction containing a major proportion of the effector cells. These data indicate that the cytotoxic lymphocyte in this system is Fc receptor positive, largely complement receptor negative, and may possess low density or low affinity receptors for SRBC.     

A human lymphoid cell line with receptors for both sheep red blood cells and complement

The human lymphoid cell line MOLT 4, from a patient with acute lymphocytic leukemia, was initially considered to be derived from T lymphocytes, on the basis of rosette formation with sheep erythrocytes (E). This cell line has now also been found to form rosettes with sheep erythrocytes sensitized with rabbit antibody and mouse complement (EAC). Evidence is presented that the formation of both E and EAC rosettes is due to two separate receptors on the MOLT cells: (a) EAC rosettes were formed more rapidly and were more stable than E rosettes; (b) preincubation of MOLT with an EAC membrane preparation inhibited resetting with EAC and not with E; (c) MOLT formed rosettes with EAC prepared from trypsinized E, but did not bind to trypsin-treated E alone. The implications of this finding, in regard to the derivation of this cell line, are discussed.     

The interaction of monomeric and complexed mouse monoclonal IgG with rat basophilic leukemia cells: a subset of IgG molecules can bind to RBL cell Fc receptors for IgG

Rat basophilic leukemia (RBL) cells were shown to bind mouse monoclonal (MC) IgE and certain mouse monomeric IgG1 and IgG2b monoclonal antibodies (MAb) by using a haptenated sheep red blood cell (SRBC) rosetting assay. Rosette formation was antibody concentration dependent with all three immunoglobulin isotypes, but at least 100 times more IgG than IgE was required to form a similar number of rosettes. It was shown by FACS analysis and rosette formation that a subset (8/23) of the IgG MC was able to bind to RBL cells as monomers. However, the majority 15/23 did not bind or bound weakly (less than 25% rosettes) unless in the form of antigen-antibody complexes. As complexes, all IgG subclasses except IgG3 could produce rosettes with RBL cells. None of the IgM or IgA MC tested formed rosettes, even in complexed form. By inhibition studies it is demonstrated that mouse IgG1, IgG2a, and IgG2b MC bind to the same Fc receptor. Mouse IgE was only partially able to inhibit IgG-dependent rosettes at high concentrations, and none of the IgG MC were able to inhibit IgE-dependent rosettes. These results suggest that the interaction of mouse IgG is quite specific for the RBL cell FcG receptor. Because deaggregated polyclonal mouse IgG was a weak inhibitor of MC IgG sensitization of RBL cells, the results are discussed in terms of the heterogeneity and possible abnormality of some MAb.