Intrathymic differentiation of cytotoxic T lymphocyte (CTL) precursors. I. The CTL immunocompetence of peanut agglutinin-positive (cortical) and negative (medullary) Lyt 123 thymocytes

To analyze the developmental and functional interrelationship between cortical and medullary thymocytes, the peanut agglutinin-(PNA) binding capacity was used to separate thymocytes into PNA+ (cortical) and PNA- (medullary) thymocytes. Virtually, all positively selected PNA+ thymocytes (90% of the overall thymocyte population) expressed the Lyt 123 phenotype, whereas 90% of negatively selected PNA- thymocytes expressed Lyt 1 alloantigens, about 10% being Lyt 123 thymocytes. Provided, the requirement of Lyt 1 T helper cells was bypassed by Interleukin 2, a nonspecific mediator of T help, PNA+ Lyt 123 thymocytes mounted cytotoxic T cell responses comparable in magnitude to that of peripheral T cells. Their repertoire included antigenic disparities coded for by the complete MHC complex, H-2K, I-A, H-2D, mutational events at H-2K, as well as antigenic disparities expressed on TNP conjugated- and Sendai virus-infected syngeneic cells. PNA- Lyt 123 thymocytes represent a highly reactive pool of primary cytotoxic T lymphocyte (CTL) precursors for both alloreactive and H-2-restricted CTL responses. Since PNA- thymocytes include also Lyt 1 T helper cells, PNA- responder thymocytes are able to mount autonomously (CTL responses. Our data are first to provide direct evidence that Lyt 123 cells represent a common source of alloreactive and H-2-restricted CTL precursors in unprimed lymphocyte populations. Moreover, the apparent immunocompetence of cortical PNA+ thymocytes is now explained by their lack of T helper cells.     

Thymic nurse cells: differentiation of thymocytes within complexes

Summary Thymic nurse cell complexes (TNC-c) were isolated from thymuses of BDF₁ mice at pre-determined intervals during the 12-week latency period that precedes the development of leukemias. T-cell leukemias were induced by a single i.v. injection of 50 mg/kg of methylnitrosourea (MNU). In order to clarify processes taking place in TNC-c, the complexes of mice after MNU injection were compared with TNC-c of age-matched control mice, with respect to their number per thymus, the distribution of TNC-c according to their size (the number of intra-TNC thymocytes reflects the type of TNC-c), the number of intra-TNC thymocytes that undergo DNA synthesis, and the phenotype of thymocytes inside TNC-c. During the latency period of leukemogenesis, the effects of MNU were shown to involve, in addition to changes in number of TNC-c, a decrease in the number of thymocytes incorporating labeled thymidine, viz., the number of dividing cells, thus affecting the size distribution of TNC-c types. Intra-TNC thymocytes of control mice were heterogeneous in their phenotype and represented cells at varying stages of their maturation cycle. MNU administration was followed by selective differentiation of thymocytes within TNC-c to Lyt 1-thymocytes in some and to Lyt 2-thymocytes in others, Lyt 1 and Lyt 2 being specific antigens expressed by thymocytes.     

Thymic lymphocytes. III. Cooperative phenomenon in the proliferation of thymocytes under Con A stimulation

In the present paper, the response of thymocytes to Con A is analyzed in terms of a cooperative phenomenon between medullary thymocytes, cortical thymocytes, thymic accessory cells, and interleukin 2. Medullary thymocytes respond spontaneously to Con A and produce IL-2. The addition of exogenously produced IL-2 enhances their proliferation. Small numbers of cortical (PNA+) thymocytes do not respond to Con A, even in the presence of IL-2-containing supernatant. By increasing the number of PNA+ cells per well, sensitivity to Con A and IL-2 appears. This response may be linked either to the increase in a minor PNA+-responding population and/or to the enhanced contamination by medullary thymocytes and macrophages in non-responding PNA+ thymocyte population. In this hypothesis, either the contaminating cells respond by themselves and/or cooperate with PNA+ cells to induce their proliferation. Coculture of non-responding low numbers of PNA+ thymocytes with Con A- and IL-2-containing supernatant in the presence of PNA- cells containing thymic medullary thymocytes and macrophages always produces a higher response than that of each individual population. These results show that a cooperative phenomenon occurs in the cocultures of PNA+ and PNA- thymic cells. We can show using PNA+ and PNA- thymocytes with different Thy 1 alleles, that indeed both PNA+ and populations participate PNA-thymocytes with different Thy 1 alleles, that indeed both PNA+ and PNA- populations participate in the generation of proliferating cells. We can demonstrate, by lysis experiments with monoclonal antibodies and complement that at the end of coculture, most of the proliferating cells are Lyt 1+, and part are Lyt 2+ or L3T4+. We discuss the fact that the phenotype of the cells after activation does not allow us to deduce the phenotype of their precursors. Lysis of Ia+ cells prior to coculture, reduces the level of the proliferative response but does not modify the percentage of cooperation produced by the coculture. Cooperation with medullary mature thymocytes or the presence of active Ia- accessory cells possibly able to convert to Ia expression during coculture experiments may account for these results.     

Cytofluorometric analysis of thymic lymphocytic subpopulations in mice with B-16 melanoma

Two colour flow cytometric analysis of the Lyt2 and L3T4 T-cell surface antigens on thymocytes from B16 melanoma bearing mice, reveal an altered cell phenotype. At the early stage of the neoplasia and during the growth, the phenotypes Lyt2+/L3T4- (T suppressor) and Lyt2+/L3T4+ (T immature) decrease. Conversely, Lyt2-/L3T4+ (T helper) increase. These findings suggest the hypothesis that impairment of the immune functions in B16 melanoma bearing mice could be due to a primary thymic alteration.     

Thymus cell differentiation and in vivo T-cell migration. I. Migration of lectin-selected thymocytes

The in vivo quantitative distribution and tissue positioning of mouse thymocytes selected in vitro by Lyt phenotype and lectin binding properties were examined. Lyt 1+2- thymocytes were selected for by cytotoxic elimination; peanut agglutinin (PNA) and soybean agglutinin (SBA) binding and nonbinding thymocyte fractions were separated by an agglutinin technique. Selected cell suspensions were labelled in vitro with 51chromium (51Cr) or [3H]adenosine. Labeled washed cells were injected intravenously into syngeneic recipients which were killed at 1, 24 or 48 hr. In recipients of 51Cr-labeled cells, tissues were collected for gamma counting, and the overall percentage recovery of injected radiolabel from the various tissues was assessed. Tissues collected from recipients of [3H]adenosine-labeled cells were fixed, sectioned, and processed for autoradiography; the positioning of labeled cells within the tissues was determined. Selected Lyt 1+2-, PNA-, and SBA- sets all showed significantly enhanced entry into lymph nodes and intestinal lymphoid tissues. Entry of SBA+ cells into these tissues was comparable to that of peripheral T cells. PNA- and SBA- selected sets, but not Lyt 1+2- selected cells, also showed increased localization to the spleen and lungs, and decreased localization to the liver. By autoradiography, PNA- cells entered lymphoid tissues much more than PNA+ cells, and at 1 hr fewer PNA+ cells in spleen were associated with lymphoid follicles. At 24 and 48 hr almost all labeled cells in lymphoid tissues were positioned in T-dependent areas. These results suggest that enrichment for thymocyte subpopulations described as "mature" also enriches for cells with the ability to enter lymphoid tissue. They also suggest that interactions at other tissue sites are important in the determination of in vivo migration, and that surface carbohydrate composition is an important factor in this determination.     

Expression of T-cell differentiation antigens on activated Thymocytes

The expression of Thy 1, TL, Lyt1, and Lyt2 antigens on resting and proliferating thymocytes activated by concanavalin A in the presence of interleukin 2 has been studied by conventional complement-dependent cytotoxicity assay. The predominant population of resting thymocytes has a TL⁺Lytl⁺Lyt2⁺ phenotype while the predominant population of proliferating thymocytes has a TL — Lytl⁺Lyt2⁺ phenotype. Using several separation procedures such as agglutination by peanut lectin, BSA density gradient centrifugation, and pretreatment with high dilutions of anti-H-2 serum it was impossible to obtain a 100% pure population of TL⁺Lytl⁺Lyt2⁺ cells, suggesting that the population of resting immature thymocytes contains small subpopulations of phenotypically differentiated cells. The population of proliferating thymocytes is also phenotypically heterogenous and contains cells bearing all phenotypes that were described for different stages of T-cell differentiation, including TL⁺Lytl⁺Lyt2^? and TL⁺Lytl^?Lyt2⁺ with the following approximate frequency: TL⁺Lytl⁺Lyt2⁺—27%, TL⁺Lytl⁺Lyt2^?—8%, TL⁺Lyt1^?Lyt2⁺—4%, TL^?Lytl⁺Lyt2⁺—45%, TL^?Lyt1⁺Lyt2^?—13%, TL^?Lyt1^?Lyt2⁺—3%.     

Thymic lymphocytes: II. Phenotypic modifications of thymocytes after concanavalin A stimulation in the presence of interleukin 2: Early modifications of Lyt 1+2+ subset and later proliferation of cells with more mature phenotypes

Cortical thymocytes are devoid of any immune function, as tested by presently available techniques. The ability of this subpopulation to respond to mitogens or antigens in the presence of interleukin 2 (IL-2) produced by activated mature T lymphocytes has been claimed but is still questioned. In an attempt to study the participation of the different thymocyte subsets and especially that of the cortical type, phenotypic modifications were examined during concanavalin A activation in the presence of IL-2. An immunofluorescent double labeling technique with anti-Lyt 1 and anti-Lyt 2 antibodies was used which led to the determination of four different phenotypes: Lyt 1⁺2⁺, Lyt 1⁺2^?, Lyt 1^?2⁺, and Lyt 1^?2^?. Careful analysis of cell viability in culture and expression of the results in absolute numbers of living cells per culture allowed us to follow modifications of small cellular subsets. Cultures of total thymocytes and PNA-agglutinated (enriched in Lyt 1⁺2⁺ cells) and non-PNA-agglutinated cells (enriched in Lyt 1⁺2^?, Lyt 1^?2⁺, and Lyt 1^?2^? cells) were studied. It was shown that thymocyte activation began by early phenotypic modifications which took place within the first 2 hr of culture but only when Con A plus IL-2 were used. These modifications imply the reduction of the Lyt 1⁺2⁺ pool and a compensatory enhancement of Lyt 1^?2⁺ and Lyt 1^?2^? cells, without modification of the total cell number or [³H]thymidine incorporation. These early phenotypic changes are interpreted as the modulation of antigens on the surface of Lyt 1⁺2⁺ cells. The second phase of thymocyte activation implies cell death (essentially Lyt 1⁺2⁺ cells) and cell proliferation. The cells which specifically proliferate in the presence of Con A and IL-2 are Lyt 1⁺2^? and Lyt 1^?2⁺, the latter always being present in greater number. Cell survival and absolute number of Lyt 1⁺2^? and Lyt 1^?2⁺ cells in the activated PNA^?-enriched population are always higher than in total thymocyte and PNA⁺ cells cultures. Thus, if Lyt 1⁺2⁺ cortical thymocytes do not proliferate by themselves, they seem to intervene by providing Lyt 1^?2⁺ cells which proliferate secondarily.     

Distribution of Lyt antigens on the surface of thymocytes associated with thymic macrophages and dendritic cells

Summary Thymocyte subpopulations that are associated with macrophages and dendritic cells of the thymus in vivo were isolated from the thymuses of C57Bl/6 mice, and their Lyt phenotypes were analyzed. Electron-microscopic examination of immunogold-labeled cells revealed that the thymic complexes formed by macrophages mainly contained Lyt-2-positive thymocytes, while Lyt-1-positive thymocytes were more frequently associated with dendritic cells. The characteristic distributions of Lyt antigens on the surface of thymocytes in regions of reciprocal contact with macrophages (Lyt-2-positive cells) and dendritic cells (Lyt-1-positive cells) suggest that these antigens play a role in specific interactions between thymocytes and stroma cells.Dedicated to Professor Dr. T.H. Schiebler on the occasion of his 65th birthday     

Expression of T cell receptors by thymocytes: in situ staining and biochemical analysis.

We have examined the in situ expression of T cell receptor (TCR) V beta 8 protein in murine thymus during ontogeny using the monoclonal antibody F23.1. Positive cells were first detected at day 15 of gestation (0.6%). By day 16 the frequency of positive cells increased dramatically (4.18%). From day 16 to day 17 positive cells doubled (8.17%). The first clusters of F23.1 positive cells were seen at day 17. In the cortex, positive cells decreased from 14% in the newborn mice to 9.8% in 8-week-old mice, whereas in the medulla the frequency remained unchanged at 20%. The antibody F23.1, as well as an antiserum raised against the constant region of the beta chain, immunoprecipitated receptor dimers from highly purified Lyt2+, L3T4+ thymocytes and from two thymic lymphomas of cortical phenotype which express full size alpha and beta mRNA. The receptor dimer could not be precipitated from Lyt2-, L3T4- thymocytes. The results are discussed with regard to intrathymic T cell repertoire selection.     

T-cell responses induced by the parenteral injection of antigen-modified syngeneic cells. II. Mechanisms, specificity, and cellular analysis of 2,4,6-trinitrophenol (TNP)-specific cytolytic response priming by intravenous versus subcutaneous injection with TNP-modified syngeneic cells

We have examined the underlying mechanisms accounting for the enhanced in vitro TNP-specific cytotoxic T-lymphocyte (CTL) response following the parenteral injection of syngeneic hapten-modified lymphoid cells. Augmented CTL activity noted following parenteral injection (iv vs sc) of 2,4,6-trinitrophenol-modified syngeneic spleen cells (TNP-SC) is most apparent when limiting numbers of TNP-modified stimulator cells are used in the in vitro sensitization phase. Enhanced CTL responses seen following sc and iv priming is due to distinct mechanisms. Spleen and lymph node (LN) cells from sc primed mice were found to contain significant levels of radioresistant helper activity upon coculture with either viable normal spleen cells in bulk culture or with thymocytes as the source of precursor CTLs in a limiting dilution assay. The helper activity was found to be mediated by a Lyt 1+2- T cells. In addition, Lyt 2-depleted spleen and LN cells from sc primed BALB/c mice could restore the ability of tolerant spleen cells from 2,4,6-trinitrobenzenesulfonic acid (TNBS)-injected BALB/c mice to generate TNP-specific CTLs. Conversely, Lyt 2-depleted spleen and LN cells from iv primed mice provided no measurable helper activity either in bulk culture or in the limiting dilution assay and did not restore the ability of TNBS-tolerant BALB/c spleen cells to generate TNP-specific CTLs. CTL priming via the iv route was found to be completely antigen specific as iv injection of either 2,4-dinitrophenol (DNP)- or fluorescein isothiocyanatel (FITC)-modified cells caused no enhanced CTL activity. Priming via the sc route exhibited a unique specificity pattern as it was shown that sc injection of both TNP-SC and DNP-SC, but not FITC-SC, resulted in enhanced TNP-specific CTL responses. CTL T-helper (Th)-cell induction via the sc route was correlated with (1) the presence of H-2 I region determinants on the inducer cells as the sc injection of TNP-modified erythrocytes led to no enhanced CTL responses or CTL Th activity (while iv injection of TNP-erythrocytes did lead to enhanced CTL responses without detectable helper activity) and (2) the detection of both hapten-specific T-cell proliferation and Interleukin 2 (IL-2) production upon restimulation in culture. We conclude that the sc injection of TNP-SC leads preferentially to an increase of specific Lyt 1+ helper activity, while iv injection leads preferentially to an apparent expansion of Lyt 2+ prelytic effector CTLs.     

Characteristics of mouse lymphoid cells proliferating in vitro by recombinant human interleukin 2 (TGP-3): comparison between normal and nude mice

Various lymphoid cells obtained from BALB/c and BALB/c nu/nu mice were cultured in vitro with recombinant human interleukin 2 (rIL 2), and the characteristics of responder cells to rIL 2 were analyzed. Spleen cells, lymph node cells, and thymocytes except for bone marrow cells obtained from BALB/c mice remarkably proliferated in response to rIL 2. On the other hand, among lymphoid cells obtained from BALB/c nu/nu mice, only lymph node cells showed significant proliferation by rIL 2. Flow cytometric analysis revealed that mainly two types of lymphoid cells were proliferating in response to rIL 2 in BALB/c mice, i.e., Thy 1+, Lyt 1-, Lyt 2- and Thy 1+, Lyt 1-, Lyt 2+ cells. On the other hand, most of the proliferating cells were Thy 1+, Lyt 1-, Lyt 2- cells in BALB/c nu/nu mice. Treatment with various antibodies plus complement revealed that the majority of IL 2-responsive cells in BALB/c mice were Thy 1+, Lyt 1+, and Lyt 2+, although a minor part of them were Thy 1-, Lyt 1-, and Lyt 2-. On the other hand, a predominant type of the IL 2-responsive cells in BALB/c nu/nu mice were Thy 1-, Lyt 1-, and Lyt 2-, though some were Thy 1+. Nonspecific killer activity against tumor cells increased to variable extents in all of the lymphoid cells of both strains after culture with rIL 2. Our results indicate that mouse responder cells to rIL 2 have the following characteristics. First, the responder cells exist abundantly among spleen, lymph nodes, and thymus in normal mice, though their cell lineages are heterogeneous; one is of T cell lineage and the other of natural killer (NK) cell lineage. Second, nude mice are defective in the responder cells of T cell lineage but not of NK cell lineage. Moreover, the responder cells in nude mice predominantly accumulate in the lymph nodes but not other lymphoid organs.     

In situ localization of T cell receptor beta chain in the murine thymus: changes in the intrathymic distribution of thymocytes expressing beta chain during fetal development

The expression of T cell receptor beta chain in the developing thymus was examined at the light and electron microscopic levels using the monoclonal antibody F23.1. Cells expressing cytoplasmic forms of beta chain were first observed at Day 16 of gestation, while thymocytes expressing cell surface beta chain were detected about a day later. Clustering of cortical F23.1+ cells was more pronounced in fetal thymus when compared to adult. The density of F23.1+ cells in the subcapsular areas of the thymus was initially lower than that in the rest of the cortex or the medulla. Within the subcapsular and cortical areas of the thymus there was an inverse relationship between the density of F23.1+ cells and cells labeled with the lectin from Dolichos bifloris, which binds to terminal alpha-linked N-acetylgalactosamine residues preferentially expressed by L3T4-/Lyt2- thymocytes. Although this pattern was less pronounced with increasing gestational age, it was still apparent at birth.     

Intrathymic T cell repertoire after prenatal trinitrobenzene-sulfonic acid-treatment

It is still a matter of debate, whether tolerance toward self-non-MHC antigens is due to intrathymic deletion or to regulatory processes in the periphery. To further pursue this question, responsiveness toward TNP and an anti-TNP monoclonal antibody (Sp6) carrying a recurrent idiotype was evaluated in prenatally trinitrobenzenesulfonic acid (TNBS)-treated mice. In prenatally untreated as well as in TNBS-treated mice, thymocytes proliferating in the absence of nominal antigen were double negative (L3T4-/Lyt2-), but antigen-specific thymocytes were single positive (L3T4+/Lyt2- or L3T4-/Lyt2+). TNBS-treated mice differed from controls inasmuch as in their first week of life T cells proliferating in response to TNP were found in the thymus and detected at increased frequencies in the spleen. The frequency of TNP-specific thymocytes and spleen cells declined rapidly, finally reaching in the spleen a level of 20-30% of controls. Furthermore, after antigenic stimulation, the frequency of thymocytes and spleen cells proliferating in response to TNP was found to be increased in control mice, but TNP-specific T cell were no more recovered in the thymus or the spleen of tolerized mice. The same accounted for thymic and splenic T cells proliferating in response to Sp6. They were expanded in control mice after antigenic stimulation, but were undetectable in TNBS-treated mice. Thus, T cells with specificity for an internal (Sp6) and an external (TNP) antigen, provided the latter was present during ontogeny, were detected in the thymus of control and, transiently, in the thymus of tolerized mice. But, the fate of antigen-specific thymocytes was different in prenatally untreated and TNBS-treated mice. The data are interpreted in the sense that tolerance toward non-MHC antigens may be acquired subsequently to tolerance toward self-MHC antigens and possibly after imprinting of antigen specificity.     

Target cell heterogeneity in murine leukemia virus infection. III. Identification of susceptible Lyt 1+ and resistant Lyt 2+ T-cell subsets following in vitro infection with Friend murine leukemia virus

The susceptibility of splenic T-cell subpopulations to productive infection with Friend murine leukemia virus was determined after in vitro infection and stimulation with Con A. Con A enhanced the number of productively infected cells in unseparated spleen cells as well as in T-cell-enriched spleen cell fractions. Splenic T cells were fractionated into Lyt 1+ and Lyt 2+ subpopulations using both positive and negative selection techniques; susceptible splenic T cells were recovered in the Lyt 1+ fraction and specific cytotoxic treatment with anti-Lyt 1 antibody and complement reduced the number of infectious center-producing cells by greater than 87%. In marked contrast, Lyt 2+ splenic T cells were resistant to productive infection by Friend murine leukemia virus in vitro.     

Ultrastructural and immunoelectron microscopic studies on infiltrating mononuclear cells in lymphocytic submandibulitis in NOD mice

The ultrastructural relations of the infiltrating mononuclear cells to the parenchymal tissues were studied in the submandibular gland of the female non-obese diabetic (NOD) mouse. In addition, the phenotype of mononuclear cells infiltrating the submandibular gland has been determined by light and electron microscopy by using monoclonal antibodies against T-cell subsets (Thy1.2, Lyt1, Lyt2). Ultrastructurally, lymphoid cells were frequently observed around and in the acini and ducts. Some of the lymphoid cells observed in the acini and ducts were irregular in shape and sometimes sent spike-like projections into acinar and ductal cells. Immunohistochemical study demonstrated that Thy1.2+ cells were predominant among the infiltrating cells, and the majority of these infiltrating T-cells were composed of Lyt1+ cells with a small proportion of Lyt2+ cells. By immunoelectron microscopy, lymphocytes carrying Thy1.2, Lyt1 or Lyt2 antigen were identified, as is demonstrated by an electron-dense reaction product on the entire cell surface, and these immunopositive cells were frequently observed around and in the acini and ducts. Some of the Thy1.2+, Lyt1+ or Lyt2+ cells observed in the acini and ducts demonstrated a close contact with acinar and ductal cells and both Lyt1+ and Lyt2+ cells sent spike-like projections into them. Occasionally, a partial degeneration of acinar cell adjacent to the invading lymphocytes was observed. These observations suggest that T-lymphocytes are involved in the direct destruction of acinar and ductal cells in the NOD mouse submandibular glands.     

5'-nucleotidase activity of murine T-cell subpopulations separated according to their Lyt2 and L3T4 phenotypes

Murine T lymphocytes were separated by "panning" into four subpopulations, according to their Lyt2 and L3T4 phenotypes: Lyt2+L3T4+, Lyt2-L3T4-, Lyt2+L3T4-, and Lyt2-L3T4+. The activity of ecto-5'-nucleotidase in each subpopulation was measured. 5'-Nucleotidase activity was undetectable in Lyt2+L3T4+ cortical cells but was expressed in medullary Lyt2-L3T4+ and Lyt2+L3T4- T lymphocytes. The small cortical subpopulation of thymocyte precursors with the Lyt2-L3T4- phenotype expressed levels of 5'-nucleotidase comparable to the levels of medullary, mature lymphocytes. These results suggest that the use of ecto-5'-nucleotidase as a marker of the degree of T-cell maturation is questionable.     

Changes in the expression of the surface antigens of thymocytes during their cultivation with macrophages

The data on changes in expression of H-2 complex and Thy-1 antigens on cell surface of thymocytes resulting from their incubation with peritoneal macrophages has been presented. The process of joint cultivation of thymocytes with macrophages leads to significant decrease in number of cells with Thy-2-antigen and increase in that with H-2 complex antigens. An increase in H-2K+ cells in experimental thymocytes as compared to control ones was observed. No changes in H-2D expression was observed. A significant increase in Ia+ macrophages was observed after interaction with thymocytes as compared with intact mononuclear phagocytes.     

Membrane phenotype of murine effector and suppressor T cells involved in delayed hypersensitivity and protective immunity to herpes simplex virus

The membrane phenotype of T cells involved in delayed hypersensitivity (DH), protective immunity, and suppression of delayed hypersensitivity to herpes simplex virus (HSV) has been determined. T cells from immune lymph nodes transferring DH and antiviral immunity to normal recipients were characterized as Lyt 1+2-. There appeared to be no detectable antiviral role for Lyt 1-2+ cells in the transferred cell suspension. Splenic T cells suppressing the induction of DH to HSV were characterized as being both Lyt 1+2- and Lyt 1-2+ 4 weeks after their induction. At earlier times, i.e., after 7 days, the suppression was mediated solely by the Lyt 1+2- population. Thereafter, a progressive increase in the contribution of the Lyt 1-2+ suppressor was observed. Both the early and later phases of suppression were due to I-J positive cells. The nature of the two suppressor cell types is discussed in relation to suppressor cell "cascades" and to the pathogenesis of herpes simplex virus infection.     

Sequential changes of thymocyte surface antigens with presence or absence of graft-vs-host reaction following allogeneic bone marrow transplantation

Lethally irradiated AKR mice were reconstituted with C57BL/6 bone marrow cells. Though the allogeneic marrow transplantation protected AKR recipients from acute irradiation deaths, the mice given unmanipulated marrow developed severe GVHR disease, and 80% died within 50 days. The thymus and spleen from the recipient mice, following recovery of body weight between the 10th and 20th days, gradually involuted and became miniscule after Day 30. Thymocytes from recipients were found to be entirely of donor cell type by Day 15. Thereafter, however, as the graft versus host reaction (GVHR) developed, changes in sensitivity of the thymocytes to four different alloantisera directed toward donor histocompatibility antigens (H-2^b, Thy 1.2, Lyt 1.2, and Lyt 2.2) were observed and these changes were associated with changes in antigen expression or quantity of Thy 1 antigens on the thymocytes. A different pattern of changes was observed in antigen expression on thymocytes in mice given B6 marrow cells that had been pretreated with anti-Thy 1 serum which prevented initiation of graft-vs-host disease and in the mice which received marrow not so treated and which regularly led to graft-vs-host disease. By contrast, the amount of H-2 antigen on the thymocytes from chimeras with or without GVHR was elevated equally. The mechanisms of these changes are discussed.     

Both cloned interleukin 2 and purified interleukin 1 are required for optimal growth of purified L3T4+ and Lyt 2+ lymphocytes initiated by concanavalin A

Concanavalin A (Con A), cloned interleukin 2 (IL-2), purified interleukin 1 (IL-1) or two different crude preparations containing IL-1 activity alone, did not induce proliferation of rigorously accessory cell (AC)-depleted splenic L3T4+ or Lyt 2+ lymphocytes. Con A together with saturating concentrations of cloned IL-2 (100 U/ml) promoted less than 40% of the proliferative responses observed in AC-supplemented L3T4+ and Lyt 2+ T-cell cultures. The three preparations of IL-1 used supported minimal proliferation of Con A-treated purified L3T4+ or Lyt 2+ lymphocytes. However, all these IL-1 preparations promoted significant growth of the T-cell populations if AC (1%) were included in the cultures. Cloned IL-2 combined with purified IL-1 promoted proliferation of Con A-treated L3T4+ and Lyt 2+ lymphocytes achieving approximately 75% of the responses observed in AC-supplemented T-cell cultures. The additive effect of IL-1 was apparent in the presence of saturating concentrations of cloned IL-2. Finally, Con A alone induced a detectable number of both L3T4+ and Lyt 2+ lymphocytes to express IL-2 receptors as determined with the anti-mouse IL-2 receptor antibody 7D4 by immunofluorescence and FACS analysis. Purified IL-1 neither induced detectable number of L3T4+ or Lyt 2+ T cells to express IL-2 receptors nor increased the number of Con A-treated T cells bearing IL-2 receptors. We have interpreted these findings to indicate the following: Con A alone is sufficient to induce highly purified L3T4+ and Lyt 2+ lymphocytes to express IL-2 receptors. Cloned IL-2 and purified IL-1 are required for optimal growth of L3T4+ and Lyt 2+ lymphocytes and these cytokines together efficiently replace AC in growth of T cells initiated by Con A. IL-1 alone does not replace AC in Con A-induced activation of mouse T cells. IL-1 exerts potentiation on IL-2-driven growth of Con A-treated L3T4+ and Lyt 2+ lymphocytes. The additive activity of IL-1 on growth of normal T cells is not due to increased production of IL-2 in the cultures or induction of normal T cells to expression of IL-2 receptors by IL-1. We propose that IL-1 optimizes the action and/or interaction of IL-2 with its receptors on the T-cell membrane (by, i.e., increasing affinity of the IL-2 receptor for its ligand and/or stabilizing the IL-2 receptor).