The Journal of Experimental Medicine

Sanchez-Madrid, F; Nagy, J A; Robbins, E; Simon, P; Springer, T A

doi: 10.1084/jem.158.6.1785pmid: 6196430

The human lymphocyte function-associated antigen-1 (LFA-1), the complement receptor-associated OKM1 molecule, and a previously undescribed molecule termed p150,95, have been found to be structurally and antigenically related. Each antigen contains an alpha- and beta-subunit noncovalently associated in an alpha 1 beta 1-structure as shown by cross-linking experiments. LFA-1, OKM1, and p150,95 alpha-subunit designations and their molecular weights are alpha L = 177,000 Mr, alpha M = 165,000 Mr, and alpha X = 150,000 Mr, respectively. The beta-subunits are all = 95,000 Mr. Some MAb precipitated only LFA-1, others only OKM1, and another precipitates all three antigens. The specificity of these MAb for particular subunits was examined after subunit dissociation by high pH. MAb specific for LFA-1 or OKM1 bind to the alpha L- or alpha M-subunits, respectively, while the cross-reactive MAb binds to the beta-subunits. Coprecipitation experiments with intact alpha 1 beta 1-complexes showed anti-alpha and anti-beta MAb can precipitate the same molecules. In two-dimensional (2D) isoelectric focusing-SDS-PAGE, the alpha subunits of the three antigens are distinct, while the beta-subunits are identical. Biosynthesis experiments showed alpha L, alpha M, and alpha X are synthesized from distinct precursors, as is beta. The three antigens differ in expression on lymphocytes, granulocytes, and monocytes. During maturation of the monoblast-like U937 line, alpha M and alpha X are upregulated and alpha L is downregulated. Some MAb to the alpha subunit of OKM1 inhibited the complement receptor type three. LFA-1, OKM1, and p150,95 constitute a novel family of functionally important human leukocyte antigens that share a common beta-subunit.

Gaston, J S; Rickinson, A B; Epstein, M A

doi: 10.1084/jem.158.6.1804pmid: 6196431

Epstein-Barr (EB) virus-specific cytotoxic T cells, prepared from virus-immune donors by reactivation in vitro and maintained thereafter as IL-2-dependent T cell lines, have been tested against large panels of EB virus-transformed lymphoblastoid cell lines of known HLA type. Whilst the pattern of lysis of the majority of targets was always consistent with HLA-A and HLA-B antigen restriction of effector function, in several cases it was noticed that certain HLA-mismatched targets were also reproducibly lysed. When this "anomalous" lysis was investigated in detail, it was found to be directed against allodeterminants on class I HLA antigens; thus, mitogen-stimulated as well as EB virus-transformed lymphoblasts from the relevant target cell donors were sensitive to the killing, and in each case the lysis could be specifically blocked by monoclonal antibodies to class I HLA antigens. In one example the target for this alloreactive lysis could be identified as a single serologically defined antigen, HLA-Bw57, while in another example lysis was directed against a "public" epitope common to HLA-Bw35, -Bw62, and a subset of -B12 antigens. Both cold target inhibition experiments and limiting dilution analysis strongly suggested that this alloreactive lysis was being mediated by the same effector T cells that recognize EB viral antigens in the context of self-HLA. This is the first demonstration in man that alloreactive responses can be derived from within the antigen-specific, self MHC-restricted T cell repertoire.

Ptak, W; Gershon, R K; Flood, P M

doi: 10.1084/jem.158.6.1822pmid: 6196432

The passive transfer of contact sensitivity (CS) by immune cells can be inhibited with an antigen-specific T suppressor factor. This factor is composed of two subfactors: an antigen-specific subfactor made by an Ly1+ cell (PC1-F) and a antigen nonspecific subfactor made by an Ly2+ T cell (TNBSA-F). The suppressive activity of the complete factor can be eliminated by depleting the assay population of Ly2+ cells, even though it is the Ly1+ cell in the population that transfers the adoptive immunity. This suggests that the Ly2+ cell in the assay population is needed to transduce the suppressive signal to the Ly1+ effector cell of DTH. We found that an Ly2+ cell from immune animals could be induced to produce a cell free subfactor that overcame the requirement for this Ttrans cell in the suppression of CS by TsF. The induction required only PC1-F, TNP-coupled spleen cells, and resulted in the production of an antigen-nonspecific I-J+ subfactor by immune Ly2+, I-J+ cells. The need for the Ly2+ transducer cell could also be overcome by addition of an I-J+ molecule secreted by Ly1 T cells hyperimmunized to SRBC. A suppressor complex made from mixing the I-J+ molecule with TNBSA-F could directly suppress the functional activity of immune T cells not only to transfer CS, but also to deliver help to B cells in an in vitro PFC response. This suppressive complex is antigen-nonspecific and does not require Ly2+ T cells in the assay population for suppressive activity. These results indicate that effector factors of the suppressor circuit require two molecules; one that contains the functional suppressor material and one that serves as a "schlepper," a molecule needed to deliver the suppression to the appropriate target cell. The ability to construct a functional suppressor complex from two subfactors raised against different antigens, using different immunization procedures, which were isolated from factors exhibiting different functional activities suggests that certain cells of the immune system may play a universal role in "transducing" the suppressive signal.

Baud, L; Hagege, J; Sraer, J; Rondeau, E; Perez, J; Ardaillou, R

doi: 10.1084/jem.158.6.1836pmid: 6315851

To investigate the phagocytic capability of glomerular mesangial cells and the biochemical events associated with phagocytosis, rat cultured mesangial cells were incubated in the presence of opsonized zymosan (STZ) and production of reactive-oxygen species and lipoxygenase products were determined. Mesangial cells were identified on the basis of morphologic (presence of microfilaments and pattern of staining by an anti-myosin antiserum) and physiologic (contractile activity in response to angiotensin II) characteristics. No contamination by esterase-positive cells was observed. Electron microscopy revealed that the phagocytic process started after 5 min of incubation, and affected approximately 50% of the cells. Superoxide anion (.O2-) and hydrogen peroxide (H2O2) generation by mesangial cells exposed to STZ increased with time and STZ concentration. Cells incubated with zymosan particles treated with heated serum produced undetectable amounts of .O2- and 6 times less H2O2 than cells exposed to STZ. Pretreatment by cytochalasin B produced a marked decrease in STZ-stimulated production of reactive oxygen species. 3HArachidonic acid was incorporated into mesangial cell phospholipids and its release and conversion into monohydroxyeicosatetraenoic acids (HETE) was measured by radiometric high performance liquid chromatography (HPLC). Incubation with STZ markedly stimulated the release of arachidonic acid from its phospholipid stores and its transformation into 11-, 12-, and 15-HETE. Lipoxygenase inhibitors inhibited STZ-stimulated H2O2 production, whereas they did not modify the phagocytic process as shown by the absence of any effect on the uptake of 125I-STZ by the mesangial cells. This study demonstrates that a high percentage of rat cultured mesangial cells phagocytose opsonized particles. The phagocytic process results in an oxidative burst that appears to be dependent on stimulation of the lipoxygenase pathway.

Beckwith, M; Rich, S

doi: 10.1084/jem.158.6.1853pmid: 6227676

In this report we examined the possibility that suppression of the mixed lymphocyte response by MLR-TsF results from interference with IL-2 regulation of T cell proliferation. Two distinct processes of inhibition involving both a direct effect on IL-2-driven proliferation of responder T cells, and induction of a second-order suppressor cell (Ts2) were described. Exogenous IL-2 did not abrogate MLR-TsF-induced suppression, and activated responder cells from suppressed cultures expressed functional IL-2 receptors by IL-2 adsorption analysis. Thus, suppression is not due to lack of available IL-2 or to abnormal acquisition of receptors for IL-2 during T cell activation. In contrast, a profound MLR-TsF effect on IL-2-induced proliferation of HT2 cells as well as MLR-activated cells was observed even after presaturation of receptors with excess IL-2. These results differentiated the direct responder cell effect of MLR-TsF from its Ts2 inductive capacity, and localized the defect in responder cell proliferation to events occurring subsequent to IL-2 binding. When analyzed in terms of proposed models for hormone-receptor interactions, characteristic dose-response curves similarly predict a postreceptor defect. Examination of the Ts2 pathway of suppression revealed a late-acting inhibitory effect peaking 72 h after MLR initiation. A minor part of Ts2 activity was susceptible to exogenous IL-2, and may reflect a requirement for IL-2 during Ts2 expansion. However, the most significant component of Ts2-mediated suppression was resistant to excess IL-2, and IL-2 production was normal in Ts2-regulated cultures, thus ruling out limitation of IL-2 for responder cell use as the major mechanism of Ts2 suppression. The complete pathway of Ts2 suppression and its functional relationship to other MLR-TsF inhibitory activities is not yet fully understood. However, these results suggest that the ultimate mechanisms of alloantigen-induced suppression involve late events of the IL-2-dependent lymphokine cascade.

Bikoff, E K

doi: 10.1084/jem.158.6.1868pmid: 6417259

Experiments presented in this report demonstrate that specificity of the Ly1+ T cell proliferative response to NP-modified Ig is controlled by Igh-C-linked genes. In addition, we describe the mechanism whereby Igh-C-encoded molecules influence Ly1+ T cell activity. We show that Igh-C-linked control of T cell responses to NP-modified Ig is a secondary consequence of naturally acquired tolerance for self Ig. Unresponsiveness to self Ig is not due to a defect expressed functionally at the level of the antigen-presenting cell, nor is it associated with active suppression. These results suggest that tolerance for self Ig at the level of the Ly1+ T cell is due to functional deletion of Ly1+ T cell clones specific for self Ig. The possibility is considered that regulatory effects mediated by passively administered antibodies may in part be due to induction of Ly1+ T cell tolerance for self Ig.

Dekruyff, R H; Clayberger, C; Cantor, H

doi: 10.1084/jem.158.6.1881pmid: 6196433

The biologic activity of molecules synthesized and secreted by hapten-specific inducer T cells was examined. After activation, a single inducer clone secretes both antigen-specific inducer peptides as well as nonspecific factors. The nonspecific factors augment the in vitro response of B cells to sheep erythrocytes (SRBC) and Type 2 T-independent antigens. The antigen-specific molecules (ABM) induce plaque-forming cell (PFC) responses in cultures containing ABM, B cells, and antigen that links the epitope recognized by ABM with the B cell epitope. Induction of B cells by ABM is limited to B cells expressing the same I-A allele as the source of the ABM and this reflects binding by ABM to I-A products on B lymphocytes. The data reported here strongly support the view that inducer cells can activate at least some B cells by secretion of a modified form of the T cell surface receptor.

Cantrell, D A; Smith, K A

doi: 10.1084/jem.158.6.1895pmid: 6606011

T lymphocyte mitosis results from the interaction of interleukin 2 (IL-2) with specific receptors that appear only after appropriate immune stimulation. To assess the potential role of IL-2 receptor levels in determining the rate and magnitude of T cell proliferation, the expression of IL-2 receptors by lectin-stimulated human peripheral blood T cells was examined and correlated with T cell growth. Using biosynthetically radiolabeled IL-2 and anti-Tac, a monoclonal antibody that blocks IL-2 receptor binding, IL-2 receptors were found to accumulate slowly and asynchronously among lectin-stimulated T cells and to precede the onset of DNA synthesis. Moreover, a critical threshold of IL-2 receptor density appeared to be required before the commitment to cell cycle progression, as analyzed quantitatively by tritiated thymidine incorporation and flow cytometric analysis of cellular DNA content. Once maximal IL-2 receptor expression occurred, continued proliferation was IL-2 concentration dependent as assessed using homogenous immunoaffinity-purified IL-2. Upon removal of the activating lectin, IL-2 receptor levels progressively declined, and, in parallel, the rate of proliferation diminished. The decay of IL-2 receptors could not be attributed to IL-2-mediated down-regulation. Instead, renewed IL-2 receptor expression was dependent upon the reintroduction of the initial activating signal. Repetitive exposure to lectin resulted in a more rapid reexpression of maximal IL-2 receptor levels, which was then followed by an accelerated resumption of proliferation. Thus, the extent of T cell proliferation after immune stimulation depends upon the interplay of the IL-2 concentration available and the density of IL-2 receptors expressed, both of which are ultimately determined by antigen/lectin stimulation. The awareness of the transience and the antigen/lectin dependence of IL-2 receptor expression, together with the capacity to monitor T cell cultures for IL-2 receptor levels, should facilitate the initiation and maintenance of cloned, antigen-specific T cells in long-term culture. In addition, these findings suggest that, in vivo, the rapidity of acquisition of maximum IL-2 receptor levels by activated T cells and the duration of IL-2 receptor expression may well direct the magnitude of T cell clonal expansion and resultant immune responses.

Takei, I; Sumida, T; Taniguchi, M

doi: 10.1084/jem.158.6.1912pmid: 6196434

An acceptor hybridoma with a receptor that recognizes the keyhole limpet hemocyanin (KLH)-specific suppressor T cell factor (KLH-TsF) was established after the fusion of C57BL/6 splenic T cells enriched with KLH-coated petri dishes. The cloned hybridoma (34S-281) could be specifically activated by stimulation with the conventional KLH-TsF or monoclonal KLH-TsF from three different hybridomas in the absence of the relevant antigen (KLH) and it started to produce another factor that suppresses the antibody response against DNP-KLH in a KLH-specific fashion. The KLH specificity of the TsF was required for activation. The new factor was found not to bind the KLH but to be absorbed with the KLH-TsF-producing hybridoma. It is thus strongly suggested that the acceptor site has a complementary structure (antiidiotype) for the KLH-TsF. Moreover, the idiotypic determinant on KLH-TsF was found to have a structure similar to that on some of the anti-KLH antibodies, since the acceptor hybridoma was specifically killed by the conventional anti-KLH antibodies and complement. Drawing on the above results, the idiotype-antiidiotype network in the conventional antigen system is discussed.

Marti, G E; Kuo, M C; Shaw, S; Chang, C C; Demars, R; Sogn, J A; Coligan, J E; Kindt, T J

doi: 10.1084/jem.158.6.1924pmid: 6606012

The polymorphic human B cell-specific antigen, 33.1, detected by a murine monoclonal antibody, was compared by genetics and structural analysis with known human Ia antigens from a panel of DR homozygous Epstein-Barr virus-transformed B lymphoblastoid cell lines. Cells homozygous for DR 1, 2, 4, 5, and w6 were positive, while cells that are DR3,3 or DR7,7 usually failed to express this antigen. Mutant DR null, DC/MB-positive cells were 33.1 positive while DR null, DC/MB-negative cells failed to express this antigen, suggesting the segregation of 33.1 with the DC antigen. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis analysis revealed that 33.1 alpha and beta chains were of lower molecular weights than the DR alpha and beta chains isolated from the same cell line. Partial N-terminal amino acid sequence analyses were carried out for the heavy and light chains of the 33.1 antigen radiolabeled with 3H phenylalanine. The results of these analyses, in conjunction with previous data on tissue distribution, indicate that the 33.1 antigen is a non-DR but Ia-like antigen closely related to the previously defined I-A homologues, DC and DS.