Characteristics of the immunosuppressive activity of lymphoid organ cells in the process of sensitization with ram erythrocytes and exposure to antilymphocyte serum

In the adoptive transfer of cells obtained from the thymus, lymph nodes and the spleen to intact syngeneic animals the suppression of immune response was induced by lymph node cells. If the donors were previously sensitized, the cells of the thymus and lymph nodes showed suppressive activity in the adoptive transfer test. A single injection of antilymphocytic serum to the donors of lymphoid cells, previously sensitized with sheep red blood cells, enhanced the immunosuppressing action of thymocytes and lymph node cells.     

B-cell suppression of antibody response to sheep red blood cells in mice of high- and low-responding genotypes.

CBA and C57B1 mice (high and low responders to sheep red blood cells, respectively) were injected intravenously with syngeneic lymph node, marrow, spleen, or thymus cells together with sheep red blood cells (SRBC), and the production of antibody-forming cells (AFC) was assayed in the spleen. Transfer of lymph node, marrow, spleen, or thymus cells led to a significant enhancement of immune responsiveness in low-responding C57B1 mice. In contrast, transfer of marrow, lymph node, or spleen cells to high-responding CBA mice was accompanied by a decline in AFC production. These effects were magnified if syngeneic cell donors had been primed with SRBC; suppression in CBA mice and stimulation in C57B1 mice were especially pronounced after transfer of SRBC-primed lymphoid cells. Pretreatment of CBA donors with cyclophosphamide in a dose causing selective B-cell depletion completely abrogated the suppression of immune responsiveness. A large dose (10⁷) of syngeneic B cells injected together with SRBC suppressed the accumulation of AFC in both CBA and C57B1 mice. No suppression of immune responsiveness was observed after transfer of intact thymus cells, hydrocortisone-resistant thymocytes, or activated T cells. We conclude that suppression of the immune response to SRBC is induced by B cells. At the same time, there is a possibility that the addition of “excess” B cells acts as a signal, triggering suppressor T cells.     

Contact sensitivity to picryl chloride: the occurrence of B suppressor cells in the lymph nodes and spleen of immunized mice.

Mice were immunized for contact sensitivity and antibody production by painting the skin with picryl chloride. Lymph node and spleen cells taken 4 days later transferred contact sensitivity. However, cells taken at 7–8 days failed to transfer but were able to block the transfer by 4 day immune cells. These suppressor cells occurred in the regional lymph nodes, spleen and thymus. The suppressor activity of lymph node and spleen cells was due to B cells as shown by the effect of anti-θ serum and complement, nylon wool filtration and separation of EAC positive and negative cells by centrifugation on a discontinuous gradient. The transfer of fractions rich or poor in macrophages showed that the suppressor cell in the transferred population was not a macrophage. Separation using EAC rosettes suggested that B cells were responsible for the suppressor activity in the thymus.T cells isolated from the lymph nodes and spleen 7–8 days after immunization transferred contact sensitivity although the initial population was inactive. This indicates that passive transfer cells are present in the regional lymph nodes and spleen at later times after immunization but cannot be demonstrated because of the presence of suppressor B cells. However, no passive transfer cells were found in the thymus. The production of B suppressor cells required little or no T cell help and following immunization the spleens of reconstituted (B) mice were at least as active as control cells in causing suppression. There are several different suppressor cells which act in the picryl system and the B suppressor cells in immunized mice described here are distinct from the T suppressor cells in mice injected with picryl sulphonic acid.     

Regulatory substances produced by lymphocytes. V. Production of inhibitor of DNA synthesis (IDS) by proliferating T lymphocytes.

The conditions neccessary for production of inhibitor of DNA synthesis (IDS) by rat lymphocytes were investigated.In concanavalin A (Con A)-stimulated lymph node cell (LNC) cultures, IDS production was not detected in the culture supernatant during the first 24 hr, and it increased gradually after that to reach a maximum at 3 to 4 days.When the cells were pretreated with mitomycin C, IDS was not produced, suggesting that DNA synthesis of LNC or a LNC subpopulation is necessary for IDS production. In contrast, Con A-stimulated spleen cells priduced a high level of IDS within 24 hr, and its production fell off sharply thereafter. Con A-stimulated rat thymocytes also produced IDS reaching a maximum at 2 to 3 dyas. However, thymus cells from rats treated with hydrocortisone 48 hr previously did not produce IDS. This finding implies that cortisol-sensitive (cortical) thymocytes are capable of producing IDS and cortisol-resistant (medullary) thymocytes are not. IDS production by lymphoblasts was proportional to cell number and unaffected eith by cell density (1 to 10 x 106/ml) or by the concomitant presence of normal cells from spleen, lymph node, or thymus. Thus Con A-stimulated cells, after becoming blasts, appear to produce IDS automatically wihtout affecting or being affected by other cells. Both spleen and thymus cells from rats injected with a large dose of antigen (ovalbumin, 100 mg, i.p.) 24 hr in advance produced substantial amounts of IDS in culture within 24 hr in the absence of mitogen or additional antigen, but not the cells from rats injected with an immunizing dose (1 mg) of the same antigen. The cells producing IDS in the spleen were shown to be adherent to glass wool, and those in the thymus were partially so. IDS production by antigen-stimulated spleen cells was abrogated by injecting rats with bromodexyuridine (BUdR) at 0 and 12 hr after the ovalbumin. These findings suggest that a subpopulation ofadherent spleen cells (possibly resembling cortical thymocytes), which begins to proliferate within a few hours after a large dose of systemic antigen, produces IDS. This may account for increased nonspecific suppressor activity observed at the same time.     

Studies on the recirculating cells in the mouse thymus

The cells in the mouse thymus which respond to PHA and have the distribution characteristics of recirculating lymphocytes upon infusion into isologous recipients are markedly enriched 2 days after treatment of mice with proper doses of cortisone acetate. However, a similar increase is not observed in lymph nodes and spleen. During regeneration of the steroidinvoluted thymus, the proportion of recirculating thymic cells disappeared more rapidly than the relative PHA-responsiveness of the cell population. These findings indicate that all PHA-responsive thymocytes may not have recirculating capacity. The recirculating cells present in the thymus and lymph nodes have no tendency to distribute to the thymus, but tend to accumulate in lymph nodes. This fact, together with the finding that in vitro trypsin treatment of the cells temporarily abolishes their lymph node-seeking capacity, are taken as evidence that the recirculating cells in the thymus have undergone their maturation within this organ whereby they have gained membrane receptors which determine their distribution characteristics.     

The distribution of adenosine deaminase among lymphocyte populations in the rat.

Adenosine deaminase (ADA) activity was determined in young rat lymphocyte populations. The ADA-specific activity (per 10(8) cells and per milligram protein) was 3- to 10-fold higher in thymocytes than in lymphocytes from thoracic duct, lymph node, spleen, and bone marrow. The high ADA activity in thymocytes appeared to be preferentially associated with cortical thymocytes. Enrichment or depletion of cortical thymocytes by density gradient centrifugation, cortisone treatment, or selective lysis with anti-Thy-1 plus complement resulted in parallel increases or decreases in ADA levles. These results also suggested that medullary thymocytes have ADA levels similar to those of peripheral lymphocytes. "Immature" cortical thymocytes and thymocyte progenitors appeared to have low ADA activity; low enzyme levels were found in fetal thymus at 16 days of embryonic life, in the early phases of thymus regeneration, and in a "null" cell population isolated from bone marrow. This study demonstrates that ADA activity varies markedly during T lymphocyte differentiation and suggests that fundamental differences in nucleotide metabolism may exist in T cells at different stages of development.     

Antigenic relationship between medullary thymocytes and a subpopulation of peripheral T cells in the rat: description of a masked antigen.

Using differentially absorbed rabbit antisera to rat thoracic duct cells, an antigen is described which normally is expressed on the surface of T cells in thoracic duct lymph and lymph node, but which exists in a masked form on medullary thymocytes and apparently not at all on cortical thymocytes. This antigen is termed the rat masked thymocyte antigen (RMTA). RMTA on medullary thymocytes can be unmasked mechanically by sectioning in a cryostat or enzymatically by treating with neuraminidase. Trypsin destroys or removes RMTA. Nearly all the T cells in thoracic duct lymph and lymph node are RMTA⁺, whereas only 58–66% of T cells in spleen are RMTA⁺. RMTA⁺ T cells, which are cortisone resistant, reside in the paracortex and periarteriolar sheath regions of lymph node and spleen. RMTA^? T cells, which are cortisone sensitive, appear to reside in the red pulp of spleen. The results suggest that (i) two antigenically distinct populations of T cells exist in the rat, RMTA⁺ and RMTA^? T cells, (ii) medullary thymocytes are the immediate precursors of RMTA⁺ T cells, and (iii) cortical thymocytes may be the immediate precursors of RMTA^? cells.     

Properties and applications of monoclonal antibodies directed against determinants of they Thy-1 locus.

Fusion of cells of the mouse myeloma line, P3/X63-Ag8 with spleen cells from AKR/J mice immunized against C3H thymocytes or from (BALB/c x BALB.K)F1 mice immunized against AKR/J thymocytes gave rise to hybrid cell lines that continuously secrete antibodies specific for the Thy-1.2 and Thy-1.1 antigens, respectively. Monoclonal antibodies from four such cell lines were analyzed in detail. All were 19S IgM, and, in the presence of complement (C), had high lytic titers on T cells of the appropriate antigenicity. Their specificity was shown by lysis of thymocytes from Thy-1 congenic mouse strains, A/J(Thy-1.2) and A. Thy 1.1. Furthermore, they lyse only 60 to 70% of lymph node cells, suggesting cytotoxicity for mature T cells and not B cells. Treatment of peripheral lymphocyte populations with monoclonal antibody plus C eliminated effector cytotoxic T lymphocytes, their precursors, and the mitogenic response to Con A, but did not affect the response to LPS. Purified, fluorescein-labeled monoclonal anti-Thy-1 antibody could be used to distinguish T and B cells. Purified antibody coupled to Sepharose 6MB was used to separate viable T and B cells. Two independently isolated anti-Thy-1.2 hybridomas are indistinguishable and bind the same determinant whereas a third is unique and may bind a separate site.     

Appendix and γM-antibody formation: VII. Rosette-forming cells in rabbits immunized with sheep erythrocytes

After intravenous immunization with sheep red blood cells the rabbit spleen shows a sharp rise in the number of plaque-forming cells but there is no detectable rise in PFC in the appendix or mesenteric lymph node of the same animals. Repeated immunization via an appendicostomy blind loop results in virtually no local PFC and only a small rise in splenic PFC.In lethally irradiated animals neither thymocytes nor appendix cells alone restore the splenic PFC response. Simultaneous injection of the two cell types restores both direct and indirect plaque formation. The injected cells were labeled with tritiated adenosine and a standard rosette assay for specific antigen-binding cells applied to recipients' spleen cells following immunization. Rosettes appeared by 3 days after immunization whether thymocytes or appendix cells were labeled. Labeled rosettes were observed only in animals receiving labeled appendix cells.This result demonstrates the presence of rosette forming cell precursors in rabbit appendix cell populations and suggests that the cells of gut-associated lymphoid tissues include antibody-forming cell precursors which are normally seeded to the spleen and draining lymph nodes.     

Suppression of mixed lymphocyte reactions by alloantigen-activated spleen-localizing thymocytes.

Heavily irradiated BALB/c and C57BL/6 mice were injected intravenously with BALB/c thymocytes. At varying times thereafter spleen and lymph node cell suspensions from these animals were treated with mitomycin C and added as regulator populations to mixed lymphocyte reactions (MLR) with syngeneic responder cells. Alloantigen-activated spleen-localizing thymocytes suppressed MLR responses 40 to 95%. Suppressor activitity, manifested as a quantitative reduction in peak proliferative responses, was maximal 4 days after cell transfer. Antigenic specificity for the stimulator cell strain in MLR was not demonstrated. The effect of lymph nodelocalizing thymocytes as regulators in MLR was variable, but in most experiments these cells slightly enhanced responses. We conclude that splenic localization is an intrinsic property of the thymocyte subpopulation capable of suppressing MLR responses, and that the suppressor activity of this subpopulation is substantially enhanced by activation in allogeneic hosts.     

Enhanced suppression of blastogenic responses by weanling mouse lymphoid cells treated with tetrahydrocannabinol in vitro

The suppressive effects of delta 9-tetrahydrocannabinol (THC) on the proliferation of lymphocytes from the spleen, lymph node, and thymus of weanling animals vs adult animals to the T-cell mitogen PHA were examined. THC had a suppressive effect on thymus cells from animals of both younger and older mice. THC suppressed spleen and lymph node cells responses to phytohemagglutinin (PHA) more readily when the cells were obtained from young mice rather than older animals. Suppression by THC in the adult mice was greater in an organ containing fewer mature T lymphocytes such as the thymus in comparison to lymphocytes in secondary organs such as the spleen and lymph nodes which contain more mature lymphocytes.     

Augmentation of erythroid burst formation by the addition of thymocytes and other myelo-lymphoid cells

Bone marrow from barrier-sustained specific pathogen-free (SPF) CBA and C57BL/6 mice gave relatively low numbers of BFU-E colonies in methylcellulose culture, as compared to conventional mice. Addition of thymocytes to the marrow cultures increased the yield of BFU-E colonies more than fourfold in SPF mice but only 1.5-fold in conventional mice. Colony size was also increased. Increased yield of BFU-E colonies was also obtained by co-culture of bone marrow with lymph node cells or with bone marrow or spleen cells from 900R whole-body-irradiated mice. The effect appeared to be cellular rather than humoral. It was not reproduced by conditioned medium from thymus or pokeweed mitogen stimulated spleen cells. The helper effect of thymus cells was eliminated or reduced by freezing and thawing, or by 48 hours of incubation after irradiation. Treatment of bone marrow cells in vitro with anti-theta serum and complement did not decrease the number of BFU-E colonies. The putative helper cells appear not to be T cells, were non-adherent to the plastic culture dish, and were cortisone resistant and radioresistant. The low BFU-E colony yield from SPF mouse marrow is presumed to be largely the result of deficiency of these non-T helper cells in SPF bone marrow, rather than of BFU-E progenitor cells.     

The nature of the cells generating B-lymphocyte colonies in vitro.

B-lymphocyte colonies are grown in semi-solid agar from mouse spleen or lymph node cells in the presence of mercaptoethanol with or without added sheep red cells. High levels of colony-forming cells were present in the spleen or normal mice and nu/nu (athymic) mice but colony-forming cells were rare in the thymus and not detected in activated T-lymphocyte populations. Colony-forming cells were theta-negative and most exhibited Fc receptors. Most colony-forming cells had the sedimentation velocity of small lymphocytes, were non-adherent and had a buoyant density similar to B-lymphocytes. Colony-forming cells were radiosensitive (Do60 rads) and sensitive to cortisone. Colony formation was potentiated by the addition of adherent spleen cells or peritoneal macrophages. It is concluded that most cells forming B-lymphocyte colonies are themselves characterisable as B-lymphocytes.     

人体胸腺和周围淋巴器官内T细胞亚群和NK细胞分布的研究

本文用多种Ｔ细胞和ＮＫ细胞单抗和免疫组织化学的ＡＢＣ技术,在冰冻切片上对人扁桃体、淋巴结、牌和胸腺内Ｔ细胞亚群和ＮＫ细胞的分布进行了检测。结果显示,ＣＤ５、ＣＤ８、ＣＤ４、ＣＤ３和ＡＩＧ３阳性细胞主要分布在扁桃体,淋巴结的副皮质区、脾的动脉周围淋巴鞘和胸腺,但各种抗体的反应强度不同。从各种Ｔ细胞工群的染色强度和形状看,胸腺髓质部的胸腺细胞相当于周围淋巴器官内的胸腺依赖区。胸腺内Ｔ细胞在分化过程中,质膜上的抗原也有相应变化。ＮＫ细胞主要分布在淋巴小结的生发中心,淋巴结和扁桃体的副皮质区,脾的红髓以及胸腺的筋质部。这些不同的分布,说明ＮＫ细胞不仅与淋巴小结的活动有关,可能还参与机体的免疫调节功能。     

Autoradiographic localization of sex steroid hormones in the lymphatic organs of baboons

Summary The localization of radiolabeled estradiol and dihydrotestosterone was examined in the lymphatic organs of both male and female baboons. A total of 12 baboons were divided into two groups, each containing three males and three females. Each animal in one group, both males and females, was injected intravenously with 1 g/kg body weight of ³H-estradiol while those in the second group were each injected with 1 g/kg body weight of ³H-dihydrotestosterone. As controls, one male and one female from each group also received a dose of 100 g/kg body weight of the corresponding unlabeled steroid. One and a half hours after the injections, the animals were sacrificed and the spleen, thymus, and inguinal lymph nodes removed and processed for autoradiography. The localization of ³H-estradiol was similar in both males and females. In the thymus fibroblasts and epithelio-reticular cells, but not thymocytes, localized ³H-estradiol. In lymph node and spleen, nonlymphoid tissue concentrated the labeled estrogen. Additionally, in the paracortical region of the lymph node, an unknown cell type was labeled with estrogen. Only one male baboon demonstrated nuclear localization of ³H-dihydrotestosterone. This was observed in the reticular cells in the spleen and lymph nodes. The same cell type in the organs of the remaining animals was unlabeled.     

Inhibition of erythroid cell growth by allogeneic murine lymphocytes. Evidence for a synergism between lymph node cells and thymocytes

Murine lymphoid cells from thymus and lymph nodes were tested for synergistic response in a graft-vs-host test. The test is based on the principle that allogeneic lymphocytes inhibit erythroid cell proliferation in the spleens of irradiated mice infused with syngeneic bone marrow cells.I was observed that mixtures of thymocytes and lymph node cells from the same parental strain yielded graft-vs-host responses in irradiated F₁-hybrids higher than expected by summing the responses of the two cell populations tested separately. A similar synergistic response was obtained using mixtures of thymocytes and lymph node cells obtained from the two parental strains of the hybrid, whereas such an effect was not detected using mixtures of lymph node cells or mixtures of thymocytes from the two parental strains. Nor could synergy be demonstrated between parental strain lymph node cells and thymocytes syngeneic with the bone marrow target cells. Thymocytes obtained from one parental strain which were injected into its irradiated F₁-hybrid transformed into a population of sensitized cells in the spleens of the recipients. This transformation was suppressed by the simultaneous injection of lymph node cells from the second parental strain. Since there is a synergistic immune response by such cell mixtures it is concluded that thymocytes may enhance the graft-vs-host response of lymph node cells. Parental strain thymocytes and lymph node cells, the latter being specifically immunologically tolerant to the bone marrow target cells, failed to give a synergistic response indicating that thymocytes do not transform unresponsive lymphocytes into responsive, but rather enhance the reactivity of existing, specifically responsive cells.The results thus show that thymocytes may enhance the response of lymph node cells in this specific graft-vs-host assay.     

The expression of theta-like antigen by rat peripheral lymphocytes: serologic and functional studies.

AKR/Cum mice (Thy-1b = thetaC3H) immunized with nucleated cells from WF rat thymus, Peyer's patches, peritoneal exudate, mesenteric lymph nodes, blood, bone marrow, or spleen produced antibodies cytotoxic for ADR/J (Thy-1a = thetaAKR) but not for AKR/Cum thymocytes. The specificity of these antibodies for the Thy-1.1 (theta-AKR) antigen was confirmed by tests using thymocytes from backcross mice segregating at the Thy-1 locus. This result suggested that the rat lymphocyte antgen cross-reactive with Thy-1.1 was expressed by at least some members of each of the rat lymphoid cell populations tested. AKR/Cum mice immunized with killed rat cells also produced anti-Thy-1.1 antibodies; thus indicating that further differentiation of the injected cells was not a prerequisite for the anti-Thy-1.1 response. Unexpectedly, about 9% of unimmunized adult AKR/Cum males were found to be producing antibodies against Thy-1.1. To our knowledge, natural antibodies of this specificity have not been previously reported. Finally, it was found that peritoneal exudate cells taken from WF rats previously immunized with EL-4 mouse leukemia cells were neither killed nor functionally inactivated by treatment with anti-Thy-1.1 antibodies and complement.     

IgM complex receptors on subpopulations of murine lymphocytes.

Murine lymphocytes from spleen, lymph node, and thymus were examined for IgM complex receptors. Lymphocytes from all three organs were found to bind SRBC sensitized with IgM from various sources including: primary anti-SRBC serum, murine and rabbit anti-Escherichia coli LPS sera, and a murine IgM myeloma (MOPC 104E). Rosette formation by lymphocytes with IgM-sensitized SRBC was inhibited by soluble antigen-IgM complexes but not by IgM or antigen alone. Rosette formation was also inhibited by human IgM (Fc)5mu but not by Fab mu. Antiserum and complement treatment of the cells and subsequent recovery of the viable cells by trypsinization, filtration, and washing revealed the IgM rosette-forming cell (RFC) in the thymus to be a T cell. Spleen on the other hand was found to contain both B and T cells capable of binding IgM sensitized SRBC. Removal of both B and T cells from spleen cell suspensions eliminated all IgM RFC. The IgM complex receptor was found to be trypsin insensitive. Anti-Ig column fractionation enriched IgM RFC in spleen and lymph node suspensions passed through the columns, whereas cells bearing surface Ig, IgG complex receptors, and C3 receptors were retained in the columns.     

Effect of cortisone-resistant thymocytes on endogenous colony formation in inbred mice]

Endogenous colonies in the spleen of sublethally irradiated (CBA X C57BL/6) E1 hybrid mice were recorded after the injection of thymocytes and the lymph node cells from the hydrocortisone-treated and intact CBA mice. Cortisone-resistant thymocytes failed to suppress the endogenous colony formation, whereas the lymph node cells produced a distinct suppressive effect on the endogenous colonies. After the injection of cortisone-resistant thymocytes the number of colonies in the spleen of individual recipients was double that in control irradiated hybrids.     

Migration of putative progenitor T cells in response to thymus-derived chemotactic factors

Progenitor T cells reach the thymus through the circulation from hematopoietic organs and then migrate toward the site of differentiation in the thymus. The mechanism that regulates such intrathymic migration is not well understood. In order to clarify this mechanism, in vitro chemotactic activity for murine thymocytes was assayed in the extracts and culture supernatants of thymic tissue elements. A potent thymocyte chemotactic activity was found in the extract and culture supernatant from Ig-, Ia- thymic stromal cells. Peanut agglutinin-positive (PNA+1), Thy 1+, TL-, Lyt 1+2-, L3T4- thymocytes, Ig-, Thy 1- bone marrow cells, and mononuclear cells of spleen and peripheral blood, but neither B cells nor lymph node cells, were chemotactically attracted by the factor(s). The chemotactic activity was found in none of the following materials tested: the extract and culture supernatant of thymocytes, culture supernatant of lymph node stromal cells, normal mouse serum, and zymosan-activated serum. The chemotactic activity was found in three molecular fractions by gel chromatography. The activity in all three fractions was destroyed by trypsin digestion or by heating at 56 degrees C for 30 min. These results suggest that Ig-, Ia- thymic stromal cells but not thymocytes secrete a chemotactic factor(s) for progenitor T cells with three molecular species. The factor is considered to play an important role in the migration of intrathymic progenitor T cells into the site of differentiation.