Evidence for an intercellular covalent reaction essential in antigen-specific T cell activation

The inductive interaction between class II+ APC and Th cell was investigated in a human system at the chemical level. The study set out to test the predictions of a model of Ag presentation in which epsilon-amino groups and carbonyl groups at the surface of APC and T cell react covalently to form reversible intercellular Schiff bases. In the experimental system of oxidative mitogenesis this process results in T cell activation. If oxidative mitogenesis is an experimental amplification of a physiologic process, and intercellular Schiff base formation is essential in Ag presentation, then it should be possible to inhibit Ag presentation by prior formation of Schiff bases on the surface of participating cells. In this situation Ag-induced T cell activation and T cell activation induced by periodate oxidation should invariably behave in the same way. It should also be possible to demonstrate Schiff base formation occurring between accessory cells and lymphocytes directly and definitively by means of specific reduction with sodium cyanoborohydride. Aldehyde treatment of accessory cells should prevent this intercellular Schiff base formation. In this study the following observations were made. 1) Both Ag-specific and periodate-induced T cell activation were inhibited by aldehyde treatment of class II+ accessory cells. 2) Noncross-linking donors of carbonyl groups other than aldehydes inhibited Ag-specific T cell activation. 3) Brief, low-dose treatment of T cells with aldehydes inhibited Ag-dependent T-cell activation. 4) Exogenous amino groups in the form of lysine and other amino acids inhibited both Ag-specific and periodate-induced T-cell activation. 5) The weak reducing agent sodium cyanoborohydride which is specific for Schiff bases at neutral pH inhibited both Ag-induced and periodate-induced T cell activation. Responses to PHA were markedly prolonged by this reagent. 6) Schiff base formation occurring between accessory cells and lymphocytes was detected directly and definitively by means of radiolabeling with NaCNB(3H)3 at neutral pH. These data are consistent with the view that the formation of reversible covalent Schiff bases between ligands on APC and T cell is an essential process in Ag-induced T cell activation.     

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.     

Probabilistic modeling of rosette formation

Rosetting, or forming a cell aggregate between a single target nucleated cell and a number of red blood cells (RBCs), is a simple assay for cell adhesion mediated by specific receptor-ligand interaction. For example, rosette formation between sheep RBC and human lymphocytes has been used to differentiate T cells from B cells. Rosetting assay is commonly used to determine the interaction of Fc gamma-receptors (FcgammaR) expressed on inflammatory cells and IgG coated on RBCs. Despite its wide use in measuring cell adhesion, the biophysical parameters of rosette formation have not been well characterized. Here we developed a probabilistic model to describe the distribution of rosette sizes, which is Poissonian. The average rosette size is predicted to be proportional to the apparent two-dimensional binding affinity of the interacting receptor-ligand pair and their site densities. The model has been supported by experiments of rosettes mediated by four molecular interactions: FcgammaRIII interacting with IgG, T cell receptor and coreceptor CD8 interacting with antigen peptide presented by major histocompatibility molecule, P-selectin interacting with P-selectin glycoprotein ligand 1 (PSGL-1), and L-selectin interacting with PSGL-1. The latter two are structurally similar and are different from the former two. Fitting the model to data enabled us to evaluate the apparent effective two-dimensional binding affinity of the interacting molecular pairs: 7.19x10(-5) microm4 for FcgammaRIII-IgG interaction, 4.66x10(-3) microm4 for P-selectin-PSGL-1 interaction, and 0.94x10(-3) microm4 for L-selectin-PSGL-1 interaction. These results elucidate the biophysical mechanism of rosette formation and enable it to become a semiquantitative assay that relates the rosette size to the effective affinity for receptor-ligand binding.     

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。     

Serologic cross-reactivity of T11 target structure and lymphocyte function-associated antigen 3. Evidence for structural homology of the sheep and human ligands of CD2

T11 target structure (T11TS) and lymphocyte function-associated antigen (LFA) 3 are the cell-surface glycoproteins on sheep and human erythrocytes (E) binding to cluster differentiation 2 (the E-receptor) on T cells in E rosette formation. Here we show that this functional cross-reactivity is most likely due to a structural homology of these molecules. A rabbit antiserum to sheep T11TS is shown to cross-react with LFA-3 in several independent assays: (a) rabbit anti-T11TS antiserum blocks the formation of E rosettes by human T cells with both autologous and xenogeneic (sheep) E by binding to the respective E; (b) the antiserum blocks the binding of anti-LFA-3 monoclonal antibody to human E; and (c) it reacts with purified LFA-3 in Western blotting. Together, these findings demonstrate that T11TS on sheep E and LFA-3 on human E are serologically related, providing further support for the notion that T11TS and LFA-3 are the sheep and human forms of the same cell interaction molecule.     

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.     

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.     

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.     

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.     

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.     

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.     

Rosetting of human T lymphocytes with sheep and human erythrocytes. Comparison of human and sheep ligand binding using purified E receptor

Previous studies have shown that the purified T lymphocyte glycoprotein, cluster differentiation 2 (CD2) (also known as T11, lymphocyte function-associated antigen (LFA)-2, and the erythrocyte (E) rosette receptor) interacts with the LFA-3 molecule on human E. We have examined the interaction of the purified CD2 molecule with the T11 target structure (T11TS) molecule on sheep E, and compared the two interactions. Purified, 125I-labeled CD2 bound to sheep E and the binding was inhibited by anti-T11TS monoclonal antibody (mAb). Reciprocally, the binding of T11TS mAb to sheep E was inhibited by pretreatment of sheep E with purified CD2. High concentrations of purified CD2 aggregated sheep E, possibly by inserting into the membrane, and the aggregation was inhibited by T11TS mAb. The affinity and number of binding sites for purified CD2 on sheep and human E was found to be similar, with Ka of 9 X 10(7)/M and 6 X 10(7)/M and 9800 and 8300 CD2 binding sites/E, respectively. Thus, the human T lymphocyte CD2 molecule is a receptor that cross-reacts between LFA-3 on human E and T11TS on sheep E, suggesting that LFA-3 and T11TS are functionally homologous ligands. As measured by saturation mAb binding, there are 8100 and 3900 ligand molecules/sheep and human E, respectively. Human and sheep E have surface areas of 145 and 54 micron 2, respectively. The 3.2- to 5.6-fold higher ligand density on sheep E appears to account for the ability of sheep but not human E to rosette with certain types of human T lymphocytes.     

人和猴T淋巴细胞表面TRBC受体和E受体的比例研究

In 1985, rosette formation of human and macaque pan-T lymphocytes with tree shrew red blood cells (TRBC) (TRBC rosette) was first found by Ben K et al, showing different physico-chemical properties from that of rosette formation with sheep red blood cells (E-rosette). In order to approach the correlation between TRBC receptor, E receptor (CD2) and other differentiation antigens (CDs) on T lymphocytes, rosette inhibition assay and antigenic modulation or co-modulation were performed with monoclonal antibodies (McAbs) to CDs, and the distribution of TRBC receptor in other peripheral immunocytes, cell lines was also examined. TRBC rosette appeared in 88.8% of E rosette positive peripheral blood lymphocytes (E(+)-PBL) and in 4.16% of E(-)-PBL. TRBC receptor was also found on all T cell lines tested (CEM, H33 HJ-JA 1, Jurkat, MLA-144, Molt-3, Molt-4, Molt-4 clone 8, PEER) and some myeloid lines (U 937 and HL 60), but not on human granulocytes, B cell lines (Daudi, Raji and Reh) and myeloid line K 562. The modulation or co-modulation of CD 3, TCR, CD 5, CD 6 and CD 7 with McAbs OKT 3, T 108 (F 1), T 136 (F 101-15), T 149 (M-T 604) and T 152 (7 G 5) did not affect TRBC rosette formation of PBL. TRBC rosette of human and rhesus monkey PBL was not inhibited by T 11.1 McAb OKT 11 (CD 2 McAb), in contrast human and rhesus monkey E rosette formations were obviously blocked at inhibition rates of 77.9% and 49.3%, respectively.(ABSTRACT TRUNCATED AT 250 WORDS)     

人和猴T淋巴细胞表面TRBC受体及其配体不同于E2分子和CD2的配体

CD2 (E receptor, LFA-3 receptor) and E2 molecules (Bernard, 1988) on human T lymphocytes, CD58 (LFA-3, lymphocyte function associated antigen 3) on human erythrocytes and S14,S42,S110-220 molecules (Bernard, 1987) of sheep erythrocytes are involved in rosette formation of human T lymphocytes with human or sheep erythrocytes. Rosette formation of human and macaque pan-T lymphocytes with tree shrew (Tupaia belangeri) red blood cells (TRBC) (TRBC rosette) has shown different physicochemical properties from that of rosette formation with sheep red blood cells (E rosette) (Ben, 1985). CD2, CD3/TCR complex, CD5, CD6, and CD7 are not involved in TRBC rosette formation (Zheng, 1990). In order to know whether E2, LFA-3,S14,S42 and S110-220 molecules are involved in TRBC rosette formation or human and macaque T lymphocytes, rosette inhibition and antigenic modulation or co-modulation were performed with relevant monoclonal antibodies (McAbs), and hemolytic assay and slide agglutination were also conducted. TRBC rosette formation of human and rhesus monkey PBL was not blocked by E2 McAb (inhibition rate 2.8% and 2.1%, respectively). In contrast, human E rosette formation was obviously blocked at inhibition rate of 49.8% and macaque E rosette formation was slightly inhibited (13.3%). The modulation or co-modulation of E2 molecule with E2 McAb did not affect human TRBC rosette formation. Similar results were shown in rosette formation inhibition of Jurkat cells.(ABSTRACT TRUNCATED AT 250 WORDS)     

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.     

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.     

Three different erythrocyte surface molecules are required for spontaneous T cell rosette formation

We have obtained three anti-sheep erythrocyte (E) monoclonal antibodies (MAb) which block rosettes with human T cells. They also block rosettes with E from all the species we have tested, including rosettes with autologous E. They define three different minor components on the E surface: MAb N217 precipitates a single 42-kilodalton (kDa) chain and MAb N4 a single 14-kDa chain, and MAb N23 immunoprecipitates under nonreducing conditions a single band at approximately 220 kDa, which is resolved under reducing and alkylating conditions, in two bands migrating at approximately 110 kDa and approximately 220 kDa. Thus MAb N23 is likely to react with a complex made of covalently linked 100-kDa chains associated in a noncovalent fashion with approximately 220 kDa chains. In addition, we have observed a puzzling phenomenon, i.e., that binding the MAb N23 first increases, to a large extent, the amount of N4 epitopes which can be subsequently detected on E. This effect was not observed when N217 MAb or antiglycophorin (either monoclonal or polyclonal) antisera were first bound on E. Therefore the N23 and N4 molecules must interact on the E surface. This finding discloses the complex interactions between the T cell and E surface component that must occur in the process of rosette formation, including that with autologous E. These observations are of interest in view of the recent evidence that the CD2 molecule is involved both in adhesion and activation aspects of T cell functioning.     

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.     

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.     

Inhibition of T-lymphocyte rosetting by HL-A alloantisera and complement.

The relationship between HL-A antigens and rosetting of sheep red blood cells (SRBC) with peripheral human lymphocytes has been investigated by incubating them with HL-A antibodies. Although sensitizing the lymphocytes with HL-A alloantisera had no effect on their ability to form rosettes with SRBC, further sensitization with C6 deficient rabbit serum as a source of early complement components inhibited the formation of rosettes with SRBC. The involvement of HL-A alloantibodies in the inhibition of rosette formation was shown first by correlating the HL-A phenotype of the lymphocytes and the HL-A specificity of the alloantisera and, second, by specifically absorbing the HL-A alloantibodies from the alloantisera. Complement was needed to inhibit rosette formation since this effect was lost when rabbit serum was treated to inactivate complement. The participation of complement's classical pathway in rosette inhibition was shown by chelating the Ca2+ ions by EGTA treatment of the C6 deficient rabbit serum. Perhaps, binding of HL-A antibodies and early complement components to the lymphocyte surface disturbs the distribution of the receptors or affects the charge of the cell membrane, thus inhibiting the rosette formation with SRBC.