Analysis of the role of xenogeneic antigens in the proliferation of human T cells stimulated with autologous non-T cells and phytohemagglutinin-activated T cells

Since conflicting results have been reported about the role of xenoantigens in the proliferation of T cells stimulated with autologous non-T cells, the effect of the exposure of cells to xenogeneic proteins during the isolation procedure and/or the culture period on autologous mixed lymphocyte reactions (AMLR) with non-T cells and phytohemagglutinin-activated T cells as stimulators was investigated. T and non-T cells were isolated by rosetting with 2-aminoethylisothiuronium bromide-treated sheep red blood cells (AET-SRBC), by nylon-wool nitration, and by positive or negative selection with anti-class II HLA antigens and anti-T-cell monoclonal antibodies. Isolation and cultures were performed in presence of fetal calf serum (FCS) or of autologous serum. In both types of AMLR, proliferation of responding cells did not require exposure to xenoantigens. However xenoantigens enhanced the proliferation of cells from some, although not all, the donors tested. There were differences in the degree of proliferation of the cells from the donors tested, but without correlation with the two types of AMLR. These results suggest that both types of AMLR reflect a self-recognition event and not a response to xenoantigens. However the potential interference of xenoantigens, as well as the individual variability, should be taken into account when interpreting the significance of abnormalities of AMLR in immunopathologic processes.     

HLA-DR antigens render resting T cells sensitive to interleukin-2 and induce production of the growth factor in the autologous mixed lymphocyte reaction

Monoclonal anti-HLA-DR (anti-Ia) antibodies inhibited autologous mixed lymphocyte reactions (AMLR) when added from the initiation of the cultures, but not 72 hr later. The suppressive principle was removed by the stimulator non-T cells, but not by the responding T cells. Antibody-treated non-T cells lost their ability to activate T cells, whereas antibody-treated T cells could still respond to untreated non-T cells. The anti-DR antibodies prevented T cells from acquiring responsiveness to Interleukin-2 (IL-2). However, T cells previously activated by AMLR responded to IL-2 even in the presence of the anti-DR antibodies. OKT4⁺ lymphocytes synthesized IL-2 in the AMLR while OKT8⁺ cells did not. Anti-DR antibodies caused OKT4⁺ cells to become unresponsive to Interleukin-1 stimulation and inhibited the production of IL-2. Interleukin-1 (IL-1) promoted the synthesis of IL-2 in non-anti-DR-treated AMLR cultures. Since resting T cells are unresponsive to IL-2 and resting OKT4⁺ lymphocytes are unable to produce IL-2 even in the presence of IL-1, it is concluded that HLA-DR antigens render resting T cells sensitive to IL-2 and enable OKT4⁺ lymphocytes to respond to IL-1 and subsequently, to produce Interleukin-2.     

Selective suppression of the murine autologous mixed lymphocyte reaction by physiological concentrations of hydrocortisone: effects on cell-surface Ia antigens

Strong, adult (Type II) autologous mixed lymphocyte reactions (AMLR) were observed in cultures of lymphoid cells from both A.TH and A.TL mice. These were suppressed by more than 90% in the continuous presence of 7.5 × 10^?8M hydrocortisone-21-sodium succinate. This concentration of hormone had minimal effects on the allogeneic mixed lymphocyte response (MLR) and the mitogenic response to concanavalin A (Con A). Higher concentrations suppressed all three responses. Treatment of autologous cell mixtures for the first 30 hr with 7.5 × 10^?8M hydrocortisone resulted in a 78% suppression of the AMLR. This was not associated with a detectable decrease in the quantity of Ia antigens on the stimulator-cell surface, as evaluated by the susceptibility of treated cells to antibody dependent, complement-mediated lysis, using [A.TH × B.10M]F₁ anti-A.TL antiserum. Hence, this suppression did not appear to result from an alteration of the antigens putatively associated with stimulation of the AMLR. Separate pretreatment of stimulator and responder cells with 7.5 × 10^?8M hydrocortisone followed by culturing with appropriate companion cells had no major effect on the AMLR. Therefore, low-dose hydrocortisone did not appear to selectively eliminate or permanently inactivate subpopulations of responder or stimulator cells. Rather, it appeared to regulate active cellular processes that are initiated by the coculturing of these cells and are required for the early stages of autologous lymphocyte activation.     

The alpha chain,not the beta chain of HLA-DR antigens participates in activation of T cells in autologous mixed lymphocyte reaction

Using antisera against the alpha, the beta or the complex of both chains of HLA-DR antigens, we have studied the role of individual chains of HLA-DR antigens in activation of T cells in autologous mixed lymphocyte reaction (AMLR). Alpha chain-specific antibody, not anti-beta chain serum prevented T cells from acquiring responsiveness to interleukin-2 (IL-2), suppressed the production of 1L-2, and inhibited the T cell proliferative response in both primary and secondary AMLR cultures. However, proliferation of already activated IL-2 reactive T cells supported by IL-2 was not affected by any of the four different types of anti-DR sera used. Fifty to sixty percent of T cells activated by AMLR or by PHA possessed DR antigens and functioned well as stimulator cells in secondary AMLR cultures. Moreover, the stimulatory activity of these DR-positive T cells was suppressed by the anti-alpha chain, not by the beta chain-specific antibody. Since continuous proliferation of T cells requires IL-2 and since nonactivated T cells are not sensitive to IL-2 and are unable to absorb this growth factor, we conclude the following: (1) The alpha, not the beta chain of HLA-DR antigens seems to be the structure responsible for enabling resting T cells to respond to IL-2 and induce production of IL-2 in AMLR. (2) Once T cells have acquired responsiveness to IL-2 and the growth factor has been produced, there is no further requirement for HLA-DR antigens, but the availability of IL-2 determines the level and extent of proliferation of IL-2 sensitive T cells.     

Improvement of decreased interleukin 2 (IL-2) responsiveness and IL-2 production in autologous mixed-lymphocyte reaction of cord blood lymphocytes by interferon-gamma and IL-2 and the role of HLA-DQ antigen

Cord blood T cells did not produce interleukin 2 (IL-2) nor acquire responsiveness to it in autologous mixed-lymphocyte reaction (AMLR) as they do when activated by phytohemagglutinin (PHA). The ability of the cells to respond to IL-2 was restored either by the addition of recombinant IL-2 to the AMLR culture or by the preculture of non-T stimulator cells with recombinant interferon-gamma (IFN-gamma). IL-2 production was also induced when the T cells were added with recombinant IL-2 at the initiation of the AMLR culture, preceded by the treatment of non-T cells with recombinant IFN-gamma. IL-2-producing cells of cord blood induced in the above-mentioned condition were defined to be OKT4+ T cells, because the deletion of OKT4+ T cells from T-cell population abrogated the reaction, while that of OKT8+ T cells did not. Acquisition of IL-2 responsiveness and IL-2 production of T cells seemed to be mediated by HLA-DR and HLA-DQ molecules of non-T cells because these reactions were blocked by the treatment of non-T cells either with monoclonal anti-HLA-DR or with anti-HLA-DQ antibody. The HLA-DR and HLA-DQ densities of cord blood non-T cells were low as compared with those of adult, but the expression of HLA-DQ was remarkably improved by IFN-gamma treatment. In regard to IL-2, both IFN-gamma and IL-2 were needed to enable the lymphocytes to produce. This may suggest that some functional maturation by IL-2 of responder T cells is further required. These combined data suggested that cord blood non-T cells are defective as a stimulator in AMLR and this could be corrected by enhancing the expression of HLA-DQ antigen.     

Cytotoxic T cells generated in the autologous mixed lymphocyte reaction. I. Primary autologous mixed lymphocyte reaction

In the course of the culture of an autologous mixed lymphocyte reaction (AMLR), T cells proliferated in response to autologous non-T cells, and differentiated to cytotoxic T cells (AMLR killers). DNA synthesis was necessary to generate AMLR killers, as the elimination of autoreactive proliferating cells with BUdR and UV light completely abrogated AMLR killer cytolysis. Amlr killers lysed various lymphoid cell lines, including autologous B cell lines, autologous or allogeneic mitogen blasts stimulated by Con A, PHA, or pokeweed mitogen, variious nonlymphoid cell lines derived from human, mouse, or rat, and weakly normal autologous or allogeneic non-T cells. KMT-17, methylcholanthrene-induced rat fibrosarcoma, was the only resistant cell line to have been tested. AMLR killers had characteristics similar to NK cells, Major histocompatibility antigens were not the target antigens for AMLR killers. AMLR killers distinguished the blasts stimulated by alloantigens as self from the blasts stimulated by mitogens as non-self.     

Stimulation of autologous and allogeneic human T cells by B cells occurs through separate B-cell antigen systems.

Studies were performed to determine the cell types involved in autologous mixed lymphocyte reactions (AMLR). Separation of peripheral blood leucocytes from normal donors into T-cell and B-cell enriched populations and subsequent co-culture of T cells and mitomycin-C inactivated non-T cells resulted in increased DNA synthesis by the responding T cells. Procedures such as removal of plastic-adherent or phagocytic cells enriched the B-cell content of the stimulator population and also enhanced stimulation of both autologous and allogeneic T cells. Velocity sedimentation separation of peripheral blood leucocytes into large and small lymphocyte fractions showed that cells which stimulate in MLR and AMLR are found in the small cell fraction and that large cells, morphologically monocytes, do not stimulate either reaction. Studies with anti-B-cell antisera obtained from multiparous women showed that the antigens of B cells which stimulate AMLR are distinct from those which stimulate MLR.     

The human autologous mixed lymphocyte reaction. I. Suppression by macrophages and T cells

The autologous mixed lymphocyte reaction (AMLR) is a proliferative response of T cells to signals from autologous non-T cells. The AMLR has been an enigma to immunologists because spontaneous proliferation of cells removed from the body is usually substantially less than that observed with a strong AMLR. However, the AMLR is thought to represent an important in vitro function, since it has the attributes of other immune responses, and it is abnormal in a variety of disease states thought to have an immune basis. We reasoned that if the AMLR represented a fundamental immune phenomenon, it should be subject to regulation. In the present study, we present evidence for suppression of the AMLR by macrophages and by T cells. Macrophages inhibited the T cell proliferation to (B + null) cells in a dose-dependent fashion and throughout the time course of the AMLR. Elimination of suppressor T cells by a specific antiserum led to an increase in the AMLR, which was again suppressed in a dose-dependent way by addition of the suppressive T cells. It may be concluded that the AMLR itself is subject to immune regulation and that the suppressive influences observed probably strongly inhibit the AMLR in vivo. Removal of the suppressive principles allows the maximal expression of the AMLR in vitro. We believe that our demonstration of regulation of the AMLR should remove the enigma associated with it and lead to a better understanding of normal cell-cell interactions as well as the basis for abnormalities in a variety of immune-mediated diseases.     

Separation of murine megakaryocytes and their progenitors on continuous gradients of Percoll

Murine bone marrow was separated on continuous Percoll density gradients to analyze the distribution of cells of the megakaryocyte lineage. Eighty-seven percent of the recovered megakaryocytes were found in fractions of density less than 1.058 g/cm3, with 63% of these cells found between 1.020 and 1.036 g/cm3. When megakaryocytes were classified according to size, 92% of the large (greater than or equal to 18 micron) acetylcholinesterase (AchE) positive cells were found in the least dense fractions (1.016-1.039 g/cm3), whereas 86% of the small (less than or equal to 10.6 micron) AchE positive cells were found in fractions of higher density (1.039-1.078 g/cm3). The distribution of enzymatic AchE activity of the separated fractions corresponded to the location of the histochemically positive cells. When ploidy measurements were made of various fractions, most of the high ploidy (32N and 64N) cells were found at low density (1.028-1.036 g/cm3), whereas no cells greater than 4N were found at density greater than 1.071 g/cm3. Thus, large AchE positive cells and the cells of highest ploidy were found at lower densities of Percoll, while small AchE positive cells and cells of low ploidy were found at higher densities. An exception to this inverse relationship was found in fractions of lowest density (less than 1.030 g/cm3) where an anomalous distribution of size and ploidy was found. The majority of megakaryocytic colony-forming cells (CFU-MK) were found at high density, as were the granulocyte-macrophage colony-forming cells (CFU-GM; approximately 1.074 g/cm3). The density distribution of the incorporation of tritiated thymidine into liquid marrow cultures was concordant with the high density distribution of colony-forming cells. The data show that megakaryocytic maturity and Percoll density varies inversely and that fractionation of marrow on continuous Percoll gradients may be a useful method for the separation and/or enrichment of megakaryocytes at different stages of differentiation.     

Allo-Ia reactive murine T-cell lines. II. Mechanisms of clonal expansion of T cells explored by use of the allo-Ia reactive T cell clones

Murine T cell clones, which were retrieved from an A.TH anti-A.TL(lak) T cell line and had been long-term cultured in the medium supplemented with T cell growth factor (TCGF) and mitomycin C(MMC)-treated feeder cells of either Is or Ik haplotype, were found to survive in TCGF-free medium for a long time, quite in contrast to so far reported TCGF-dependent T cell clones. When T cells of these clones at the full growth in the TCGF-medium were transferred to TCGF-free medium, they survived at resting state for a long time, and half-life, i.e., the time when 50% of the transferred cells were still viable, of some clones reached 20 days. The cloned T cells at the resting state retained full responsiveness to the specific lak antigen but lost the responsiveness to TCGF as determined by [3H]thymidine uptake, whereas the same T cells harvested from TCGF-medium did not show the antigen-specific responsiveness. The cloned T cells at the resting state showed marked DNA synthesis in response to the specific antigen but never entered the phase of the cell division. Addition of TCGF to the antigen-activated cloned T cells at their peak DNA synthesis triggered the cell division without time lag. Thus, it was confirmed at a single clone level that two sequential signals, one via the antigen-receptor reacting with specific antigen and another via the TCGF-receptor accepting TCGF, are required for clonal expansion of T cells reacting with antigen. The mitogen-responsiveness among five clones was examined at their resting state; two clones responded to Con A and PHA only in the presence of accessory cells (MMC-treated, T cell-depleted syngeneic spleen cells), and one clone responded well to Con A and PHA in the absence of accessory cells. Thus, most of our clones retained physiologic characteristics of T cells directly collected from mice even after long-term culture in TCGF-medium.     

Possible regulation of autologous mixed lymphocyte reaction by OKM1+ NK cells

T cells are stimulated by autologous non-T cells and interleukin 2 (IL-2) is produced in the conventional autologous mixed lymphocyte reaction (AMLR) in young healthy controls. The role of cells with natural killer (NK) cell markers (OKM1+ cells or Leu 7+ cells) in the AMLR was studied. There were significant inverse correlations between the percentage of input OKM1+ cells minus monocyte (OKM1+ NK cells) and either AMLR proliferation (gamma = -0.9, P less than 0.001) or IL-2 production (gamma = -0.75, P less than 0.01) in the AMLR cultures after 7 days measured at 7 days. A statistically significant correlation was observed between the percentage of input Leu 7+ cells and AMLR proliferation (gamma = -0.64, P less than 0.05), but not IL-2 production. These results suggest that the AMLR is controlled by OKM1+ NK, perhaps acting through IL-2 regulation.     

rIL 2-induced proliferation of human circulating NK cells and T lymphocytes: synergistic effects of IL 1 and IL 2

Cells participating in the rIL 2-induced proliferation of resting PBMC were identified by using different methods of cell purification. NK cells recovered in the light density fraction of Percoll gradients responded, as already known, directly to rIL 2 by strong proliferation. In contrast, large T lymphocytes co-purifying with NK cells, and small T cells sedimenting in the high density area of the Percoll gradients, were virtually unresponsive when cultivated in the sole presence of rIL 2. However, the addition of either irradiated autologous monocytes or highly purified IL 1 allowed both kinds of T cells to undergo cell division. Stringent elimination of possibly contaminating NK cells (NKH-1+) and/or activated T cells (TNKTAR, Tac+, HLA-DR+) from the high density T cells by complement lysis did not impair rIL 2-induced cell proliferation, indicating entire responsiveness of these cells to the synergistic action of IL 1 plus IL 2. Both high density CD4+ and CD8+ participated in this phenomenon, with an apparent advantage for CD4+ cells. All Tac+ cells emerging in a 6-day culture of these cells expressed the WT31 antigen, which indicates that T cells involved in rIL 2-induced proliferation are conventional mature T cells. The relative precursor frequencies of NK cells, large T lymphocytes, and small T lymphocytes that proliferated in response to rIL 2 were analyzed by limiting dilution analysis. The frequencies of clonal growth of NK cells and low density T lymphocytes were approximately the same (1/103 vs 1/185), whereas that of high density T cells was four times lower (1/458). Thus, we clearly demonstrate that resting T cells, defined as such by morphological, density, and phenotypic criteria, are able to proliferate in response to IL 2 in the presence of IL 1 without antigenic or mitogenic triggering.     

Further characterization of the autologous mixed lymphocyte reaction: induction of double negative gamma delta T lymphocytes.

To investigate the specific nature of the autologous mixed lymphocyte reaction (AMLR), we applied a method in which mixtures of NY-nonadherent responder cells and NY-adherent stimulator cells were treated with neuraminidase before culture and then cultured to assay the AMLR. This method produced a marked enhancement of DNA replication in the responder cells and the results were reproducible, regardless of the individuals tested. Using this method, we were able to make the following observations regarding the specific nature of the AMLR. (i) The AMLR is an IL-2-independent reaction, as revealed by bioassay to detect the presence of IL-2 by a blocking test using anti-IL-2R sera and as shown by the absence of mRNA for IL-2 in Northern hybridization. (ii) It is also HLA-DR dependent as proven by the fact that anti-DR sera almost completely inhibited the reaction. (iii) The AMLR was also found to induce the generation of activated CD4+ helper T cells in direct response to stimulation by NY-adherent cells, in which HLA-DR antigens were involved. (iv) Also, it induced the generation of CD4-CD8- double-negative (DN) lymphocytes, including gamma delta T cells with a cytotoxic activity against NK-resistant target cells and with a variety of lymphocyte activation markers (CD56, HLA-DR, CD25, transferrin receptors, CD38, and LFA-1). However, the AMLR did not induce the generation of NK cell markers CD16 and CD57. (v) The DN lymphocytes and gamma delta T cells appeared to be generated from the precursors of CD4-CD8- DN cells, in direct response to the stimulator cells. These results strongly suggest that the AMLR may be a phenomenon which induces the proliferative response of gamma delta T cells and their precursors, in addition to that of alpha beta T cells, particularly of CD4+ helper T cells.     

Helper cells in the autologous mixed lymphocyte reaction. I. Generation of cytotoxic T cells recognizing modified self H-2

The autologous mixed lymphocyte reaction (AMLR) in mice measures the proliferative response of T cells to determinants on syngeneic non-T spleen cells. Normally, cytotoxic T lymphocytes (CTL) are not generated in this reaction. However, the addition of trinitrophenyl-modified mitomycin C-treated syngeneic T cells (TNP-Tm) to the AMLR results in the generation of TNP-specific CTL but does not alter the proliferative response. Significant cytotoxic activity is not detectable against TNP in association with Ia unless TNP is present on cells bearing those determinants. Thus, if unselected spleen cells are TNP-modified and used as stimulators in the AMLR, the proliferative response is enhanced and CTL are generated that recognize TNP in association with K, D, and I region-encoded determinants. The CTL generated in the AMLR are H-2 restricted and dependent on the presence of adherent cells in the sensitization cultures. The experiments presented here suggest that the AMLR can provide the help necessary for generating cytotoxic T cells in vitro.     

Detection of autologous mixed lymphocyte reaction responding cells and their precursor frequency in NZB mice

The autologous mixed lymphocyte reaction (AMLR) can be detected in older NZB mice after treatment of the responding cell population with monoclonal anti-I-A^d and complement and supplementation of the culture medium with T-cell growth factor (TCGF) from young animals. The addition of TCGF to cultures containing responding cells alone that had not been pretreated with anti-I-A plus complement resulted in high levels of background proliferation. This is indicative of a high number of preexisting I-A-positive, activated, TCGF-responsive T cells in these mice. These activated cells could also be removed by treatment with anti-I-A antibody and panning on anti-mouse Ig plates, or by BUdR and light killing of those cells proliferating in the presence of TCGF or purified IL-2. Prior treatment of the responding cells with anti-Lyt 2 and complement did not effect the AMLR. An NZB AMLR responding cell line was established using these methods. This line retained haplotype specificity in a proliferation assay. Limiting dilution analysis of the precursor frequency of AMLR responding cells in the nonautoimmune C58 and BALB/C strains in culture medium with TCGF gave a frequency of between 1 in 35,000 and 1 in 88,000. In young, AMLR-positive, NZB mice, supplementation with TCGF yielded precursor frequencies within the normal range. In older NZB mice, the addition of TCGF resulted in increased background proliferation of preactivated, IA⁺ T cells. After removal of these cells with anti-I-A plus complement, AMLR responding cells were found at normal frequency levels when stimulated in the presence of TCGF. In the oldest animals tested (greater than 18–20 weeks), normal precursor frequencies could not be demonstrated even after this treatment, representing a true decline in the AMLR responding cell number. AMLR deficiency in NZB mice appears therefore to be the result of the combined effects of decreased lymphokine production, excessive T-cell activation, and finally decreased numbers of AMLR responding cells.     

Different baseline sister chromatid exchange levels in density fractionated human lymphocytes

Summary Different activation states of B and T lymphocytes, as manifested by differences in cell density, were obtained by Percoll density centrifugation of unstimulated human lymphocytes. Four different density fractions were defined: B cells with low (1.043 g/ml) and high (1.056) density, and T cells with low (1.067) and high (1.077) density, respectively. Sister chromatid exchange (SCE) conditions and proliferation rates were determined. Total B cells, stimulated by the bacterial mitogen Branhamella, had 4.6 SCE per cell, the lowest mean baseline SCE level recorded among lymphocytes. The growth rate was intermediate between that of low and high density T cells. The two T cell fractions stimulated by phytohemagglutinin (PHA) had different baseline SCE frequencies and different growth characteristics: the low density cells had 5.7 SCEs per cell and a short cell cycle, whereas high density cells had 12.5 SCEs per cell and a longer cell cycle. The differences in baseline SCE frequency and growth characteristics between the two T cell fractions seem to be correlated with the differences in the activation state as reflected by the cell density. Both high and low density T cell are G₀ populations which supposedly differ with respect to previous history in vivo such as age and contact with antigens. The reason why these cells react differently to bromodeoxyuridine (BrdU) is unknown, but differences in intracellular DNA precursor pools and enzyme activities might play a role.     

The effect of IL-2 and IFN-beta on autologous tumor cell kill by Percoll separated LGL fractions

Low density fractions of Percoll density gradient centrifugation of peripheral mononuclear cells contained the majority of large granular lymphocytes (LGL). LGL were used for 5-hr 51Cr release cytotoxic assay against autologous tumor cells in 20 patients with hematological malignancies (9AML, 4ALL and 7NHL). Mean % cytotoxicity (% CTX) was 6.0%, and the addition of IFN-beta and IL-2 in the medium induced the significant increase of % CTX to 15.0% and 26.1%, respectively. When LGL cultured in medium containing IFN-beta and IL-2 were assessed for cytotoxicity daily for 8 days, the enhancement of % CTX by IFN-beta was declined in a few days, while the enhancement by IL-2 was sustained for more than 8 days. The pretreatment of LGL with anti Leu-11 (CD16) plus complement abrogated the enhancing effect by IFN-beta or IL-2, but not with anti Leu-1 (CD5) plus complement. When this treatment was done on day 8 of IL-2 cocultivation, anti Leu-11 plus complement suppressed cytotoxicity significantly, and anti Leu-1 plus complement also induced mild suppression. The phenotypic characteristics of cells revealed the significant increase of anti Leu-19+ cells in IL-2 stimulated day 8 cells. High density fractions of Percoll gradient contained mostly T lymphocytes and showed no cytotoxicity against autologous tumor cells. However, cocultivation with IL-2 for 8 days induced the cytotoxicity, associated with increased number of anti Leu-19+ cells. These results suggested that IL-2 induced cytotoxic activity against autologous tumor cells might be related to the increase of anti Leu-19+ cells.     

Amplification of suppressor inducer pathway with monoclonal antibody, anti-2H4, identifying a novel epitope of the common leukocyte antigen/T200 antigen

The 2H4 antigen, comprised of a 200/220-kDa glycoprotein of the leukocyte common antigen (LCA) family, is expressed on a suppressor inducer, but not a helper inducer subset of T4 cells. Earlier studies have demonstrated that the T4+2H4+ subset of cells maximally responded to the AMLR and this molecule has an important role in generated suppressor signals in AMLR/Con A-activated T cell systems. In the present study, we examined the effect of a series of monoclonal antibodies including anti-2H4 antibody on the initial activation of T4 cells in response to self-Ia antigens. We found that the addition of anti-2H4 antibody resulted in an augmentation of the proliferative response of T4 cells in AMLR, whereas other antibodies reactive with LCA/T200 antigens lacked this ability. Furthermore, anti-2H4 antibody enhanced both IL-2 production and IL-2R expression in this AMLR system. This enhancing effect was inhibited by anti-T3 antibody. Moreover, the suppressor inducer function of AMLR T4 cells was enhanced with anti-2H4 antibody by increasing the number of 2H4+ cells with high antigen density. Taken together, these results suggest that the 2H4 antigen may serve as an accessory structure for enhancing the activation of the T4+2H4+ suppressor inducer subset at initiation of cell triggering.     

Interferon gamma modulates the ability of autologous non-T cells to stimulate T cells to produce and respond to interleukin 2

The interactions of T-cell receptor with self-Ia antigen on non-T cells induced IL-2 production and IL-2 receptors on the cell surface and thus responsiveness to IL-2 of T cells in autologous mixed-lymphocyte reaction (AMLR). Four-day-cultured autologous non-T cells lost their ability to stimulate T cells to produce and respond to IL-2 with concurrent decrease of HLA-DR and HLA-DQ antigen expressed on the cell surface. Culturing of non-T cells with 500 U/ml of recombinant interferon gamma (IFN-gamma) maintained their stimulating ability which was otherwise lost. Treatment of non-T cells with monoclonal anti-HLA-DR or anti-HLA-DQ antibody before mixture with T cells abrogated their ability to induce IL-2 production and IL-2 responsiveness of T cells. The combined data suggested that Ia antigen expressed on non-T cells is modulated by IFN-gamma, which increases the ability of non-T cells to stimulate autologous T cells to produce and respond to IL-2.     

Impaired natural killer cell function in hemophiliacs with or without continuous substitution

In the present study, 28 hemophiliacs substituted continuously and 5 hemophiliacs who had received almost no blood products were investigated. Cells of OKT 3+, OKT 4+, and OKT 8+ subsets were counted. Percoll separated fractions of peripheral blood mononuclear cells were examined by morphological criteria and were tested for NK cell activity. We found that the NK cell activity of both groups of hemophiliacs was decreased on testing Ficoll separated cells or low density Percoll separated cells. Normal NK cell activity was found in medium density cells of hemophiliacs. Two possible explanations are discussed: first, the NK cell activity may be suppressed in hemophiliacs and secondly, there may be a block in maturation of NK cell activity. It is unlikely that chronic substitution by blood products counts for these alterations. The possible role of chronic infections is discussed.