Suppressor activity in the spleen of neonatal mice

Citrulline supplementation exacerbates sepsis severity in infected preterm piglets via early induced immunosuppression

Arginine (ARG)/Citrulline (CIT) deficiency is associated with increased sepsis severity after infection. Supplementation of CIT to susceptible patients with ARG/CIT deficiency such as preterm newborns with suspected infection might prevent sepsis, via maintaining immune and vascular function. Caesarean-delivered, parenterally nourished preterm pigs were treated with CIT (1g/kg bodyweight) via oral or continuous intravenous supplementation, then inoculated with live Staphylococcus epidermidis and clinically monitored for 14 h. Blood, liver, and spleen samples were collected for analysis. In vitro cord blood stimulation was performed to explore how CIT and ARG affect premature blood cell responses. After infection, oral CIT supplementation led to higher mortality, increased blood bacterial load, and systemic and hepatic inflammation. Intravenous CIT administration showed increased inflammation and bacterial burdens without significantly affecting mortality. Liver transcriptomics and data from in vitro blood stimulation indicated that CIT induces systemic immunosuppression in preterm newborns, which may impair resistance response to bacteria at the early stage of infection, subsequently causing later uncontrollable inflammation and tissue damage. The early stage of CIT supplementation exacerbates sepsis severity in infected preterm pigs, likely via inducing systemic immunosuppression.

Immunological nonreactivity of newborn mice: immaturity of T cells and selective action of neonatal suppressor cells

Mitogen-stimulated spleen cells from newborn mice do not synthesize mRNA for the 55-kDa interleukin-2 receptor (IL-2R). The kinetic of development after birth of ability to synthesize IL-2R correlated well with the functional immaturity of T cells, as was tested by responsiveness to T-cell mitogen concanavalin A (Con A). This functional immaturity of T cells was not due to the activity of neonatal suppressor cells (NSC) which inhibited immune responses induced by mitogens or antigens. The suppressor cells did not inhibit proliferation of spleen cells stimulated with IL-1 or IL-2, nor did they inhibited expression of genes for tumor necrosis factor (TNF)-beta, TNF-alpha, and IL-2R in stimulated cells from adult mice. The results thus show functional immaturity of T cells in newborn mice and selectivity of the immunosuppressive action of NSC, which allow for production and for functional activity of cytokines at a time when the specific immune system is not functional because of both immaturity and a selective activity of inhibitory cells.

GM-CSF augments the immunosuppressive capacity of neonatal spleen cells in vitro

Addition of exogenous granulocyte-macrophage colony stimulating factor (GM-CSF) to cultures of adult murine spleen cells with sheep red blood cells (SRBC) results in an augmented plaque forming cell (PFC) response. The influence of GM-CSF on the ability of neonatal spleen cells to suppress the anti-SRBC plaque forming response of adult spleen cells was tested by adding GM-CSF to cultures of neonatal and adult spleen cells. The suppressive capacity of the neonatal spleen cells was augmented by exogenous GM-CSF. The augmented suppression of the neonatal spleen cells was dependent on a G-10 adherent population since the addition of GM-CSF to cultures containing G-10 passed neonatal spleen cells resulted in an augmented PFC response and not suppression. Neonatal splenic glass adherent cells were also capable of suppressing the response. Neonatal spleen cells or purified neonatal glass adherent spleen cells cultured in the presence of GM-CSF had markedly increased levels of PGE2 in the culture supernatant. Neonatal spleen cells cultured with GM-CSF had increased numbers of morphologically identifiable macrophages after 48 hr of culture. Both irradiation and G-10 passage of the neonatal spleen diminished the numbers of macrophages formed in response to GM-CSF, and both of these manipulations resulted in reversal of suppression in response to GM-CSF. Thus, the augmented suppressive capacity of neonatal spleen cells in response to GM-CSF is probably mediated by its ability to drive monocyte to macrophage differentiation as well as increase the suppressive capacity of the existing neonatal splenic macrophages by increasing their production of PGE2.

Regulation of thymocyte proliferation by alpha beta TcR+ CD3+ CD4- CD8- cloned natural suppressor (NS) cells

Cloned alpha beta TcR+ CD3+ CD4- CD8- T cells, with natural suppressor (NS) activity, were cocultured with thymocytes in the presence or absence of mitogen or cytokines. Whereas thymocytes show a minimal response to phytohemagglutinin (PHA), IL-2, or IL-4 alone, they proliferate vigorously when cocultured with irradiated cloned NS cells in the presence of PHA or IL-2 or IL-4, but not with IL-1, IL-3, IL-6, IL-7, IFN-gamma, or GM-CSF. Among a total of 11 NS cell clones, derived from the spleen or thymus, only one clone (NR-1) did not induce thymocyte activation in synergy with PHA. This costimulation is most likely mediated by soluble factor(s), since supernatants, obtained from NS cells activated with phorbol ester (PMA) and calcymicin (A23187) or with solid phase anti-CD3 mAb, enhance thymocyte DNA synthesis in the presence of a mixture of PHA, IL-2, and IL-4. The latter factor does not appear to be a previously described lymphokine, since PMA- and A23187-activated NS cells secrete IL-3, TGF-beta, IFN-gamma, GM-CSF, and TNF-alpha, but not IL-1, IL-2, IL-4, IL-5, IL-6, IL-7, nor IL-10. None of the factors, identified in the NS cell supernatants, was able to stimulate thymocyte DNA synthesis. This study shows that, in addition to their previously reported suppressor function, cloned NS cells can exert immunostimulatory activities by virtue of a soluble mediator.

Regression of adjuvant-induced arthritis in rats following bone marrow transplantation

Total body irradiation followed by bone marrow transplantation was found to be an effective treatment for adjuvant arthritis induced in rats. This treatment is most effective when applied shortly after the clinical manifestation of arthritis--i.e., 4-7 weeks after administration of Mycobacterium tuberculosis. Transplantation of bone marrow at a later stage results in a limited recovery, in that the inflammatory reaction regresses but the newly formed excessive bone is not eliminated. Local irradiation of the affected joints had no effect on the disease. It could also be excluded that the recovery of arthritis following marrow transplantation is due to lack of available antigen. Transplantation of syngeneic bone marrow is as effective as that of allogeneic bone marrow from a rat strain that is not susceptible to induction of adjuvant arthritis. The beneficial effect of this treatment cannot be ascribed to the immunosuppressive effect of total body irradiation, since treatment with the highly immunosuppressive drug Cyclosporin A resulted in a regression of the joint swelling but relapse occurred shortly after discontinuation of the treatment.

Does depression of NK activity cause lymphadenopathy in lpr mice?

B6-lpr/lpr mice develop massive T cell lymphoproliferation, as associated with autoimmune disease. We found a reduced NK activity in the spleen of B6-lpr/lpr mice. Neonatal thymectomy markedly retarded the development of lymphoproliferation and the development of autoantibodies in the B6-lpr/lpr mice. These animals had a higher level of NK activity in the spleen. When the neonatally thymectomized B6-lpr/lpr mice were given anti-asialo GM1 serum (30 microliter) four times at 6-day intervals, initiated at the 8th-10th postnatal week, these mice developed lymphoproliferative disorders and splenomegaly, concomitantly with depression of NK activity. It is therefore tempting to speculate that NK cells are involved in the regulation of the occurrence of lymphoproliferative disorders.

Presence of natural suppressor cells in the chicken embryo spleen and the effect of virus infection of the embryo on suppressor cell activity

Spleen cells but not the thymus or the bursa cells of chicken embryos suppressed the in vitro mitogenesis of spleen cells of adult syngeneic or allogeneic chickens. The natural suppressor cell activity of embryo spleen was present at embryonation day 16, reached peak levels at embryonation day 18 and disappeared at hatch. The embryo spleen cells did not by themselves respond to phytohemagglutinin stimulation in vitro. The suppressive effect of embryonic spleen cells on adult spleen cells was present when the embryonic cells were added at the time of or after initiation of the adult spleen mitogenic cultures. When the embryonic cells were added to the cultures of adult spleen cells after the blastogenic response of the adult cells had peaked, the embryonic cells inhibited the incorporation of the label into adult spleen cell blasts. The suppressive activity of the embryonic spleen cells was mediated by soluble suppressor product(s) secreted by these cells, and direct cell-to-cell contact between embryonic and adult spleen cells was not necessary for suppression to occur. Infection of embryos with turkey herpesvirus and Marek's disease virus reduced the suppressor cell activity of embryonic spleen, although substantial residual suppressor cell activity remained in virus-infected embryos. Several pathogenic or non-pathogenic isolates of infectious bursal disease virus did not appreciably alter the suppressor cell activity of embryonic spleen cells.

Soluble factors secreted by naturally occurring suppressor cells that interfere with in vivo graft-vs.-host disease and with T cell responsiveness in vitro

A potent immunosuppressive factor (SUF) is found in the supernatant of short-term cultures of unstimulated thymocytes or spleen cells of neonatal mice and rats and in culture medium of hybridoma cell lines established by fusing neonatal mouse spleen cells with T lymphoma cells (the BW 5147 line). In vitro incubation of spleen cells with SUF suppresses the acute in vivo graft-vs.-host disease, normally induced by allogeneic spleen cells in lethally irradiated mice. Incubation of bone marrow cells with SUF does not affect the hemopoietic stem cells. The addition of SUF to mixed lymphocyte reaction cultures strongly suppresses lymphocyte proliferation. The non-species-restricted inhibition of cell proliferation induced by SUF is shown not to be due to toxicity or nonspecific interference with DNA synthesis. Molecular size fractionation of crude SUF revealed two active moieties: a large moiety of molecular mass greater than 100 kDa and a small moiety of less than 3 kDa. The high kDa moiety mediates T cell unresponsiveness both in vivo and in vitro. In vitro studies revealed that this moiety primarily affects an early event in the proliferative response to alloantigen and mitogen, that prevents interleukin 2 (IL 2) receptor expression and, consequently, blastogenesis and DNA duplication. It does not affect, however, the synthesis of IL 2. The suppressive activity of the low kDa moiety can be demonstrated only in in vitro systems. Pre-treatment of donor lymphocytes with this fraction cannot prevent graft-vs.-host disease mortality. The inhibition of cell proliferation induced by this fraction in vitro is most likely due to interference with the utilization of IL 2, as suggested by its suppressive effect on the proliferation of CTLL-2 cells (an IL 2-dependent cell line).

Neonatal cells in the immunoregulation of parental alloreactivity

The ability of neonatal murine F1 cells to regulate parental graft vs. host (GvH) reactions was investigated. Neonatal F1 splenocytes were able to decrease significantly the deleterious effects of systemic GvH reactions induced either with maternal or paternal splenocytes in a third party strain. Both neonatal F1 splenocytes or thymocytes were able to decrease local GvH reactions induced with maternal splenocytes towards paternal histocompatibility antigens. In the same experimental conditions, however, neonatal F1 cells were unable to decrease local GvH reactions induced with paternal splenocytes towards maternal histocompatibility antigens; using different numbers of neonatal F1 cells not only was no suppressive effect detected but even, a significant increase in GvH was registered. Similar results were obtained when mortality assays were carried out. It can be concluded that neonatal F1 mice differ in their capacity for regulating parental alloreactive T reactions against self histocompatibility antigens either of maternal or paternal origin.

Murine neonatal spleen contains natural T and non-T suppressor cells capable of inhibiting adult alloreactive and newborn autoreactive T-cell proliferation

The spleen of neonatal mice is known to be a rich source of cells capable of suppressing a variety of immune functions of adult lymphocytes in vitro. From such observations has emerged the concept that the gradual development in ability to express immune functions after birth is due in part to the parallel normal physiological decay of naturally occurring regulatory suppressor cells. There is, however, some confusion in the literature as to the exact nature of the newborn of the newborn inhibitory cell type(s). In contrast to most previous reports which detect only a single type of neonatal suppressor cell, usually a T cell, we show here that newborn spleen harbors both T and non-T inhibitory cells. Both types of suppressor cells could be shown to suppress the proliferative response of adult spleen to alloantigens as well as newborn T cells reacting against self-Ia antigen in the autologous mixed lymphocyte reaction (AMLR). Newborn suppressor T cells were characterized as being non-adherent to Ig-anti-Ig affinity columns, soybean agglutinin receptor negative (SBA-), and susceptible to lysis by anti-T-cell specific antiserum plus complement. Non-T suppressor cells were identified as non-phagocytic, SBA receptor positive (SBA+), and resistant to cytotoxic treatment with anti-T-cell antibodies and complement. The apparent controversy surrounding previous reports as to the T versus non-T nature of newborn suppressor cells can be reconciled by the present observation that both types of inhibitory cells coexist in the spleen. Furthermore, the demonstration that newborn suppressor cells can effectively regulate T-cell proliferative activity mediated by other newborn cells provides more direct support for the contention that such inhibitory cells play a physiological role in controlling immune responsiveness during early ontogeny.

Naturally occurring, spleen-associated suppressor activity of the newborn mouse. Biochemical and functional identification of three monokines secreted by newborn suppressor-inducer monocytes

Immature monocytes residing in the spleens of newborn mice less than 6-7 days of age are known to suppress T-dependent and T-independent immune responses in vitro and in vivo. Suppression is mediated in part through products secreted by the newborn monocytes. In the present study, we have identified 3 monokines secreted by newborn, but not adult, monocytes correlating with materials possessing significant suppressor activity in vitro. These monokines have molecular weights of 58, 10.8, and 10 kilodaltons, appear to be proteins, and are insensitive to heat inactivation. The 58 kd material is antigenically distinct from alpha-fetoprotein, while the lower molecular weight materials are too large to be prostaglandins. Although these monokines can be shown to have activity in vitro, they are not as efficient as newborn monocytes in preventing alloreactivity in vivo.

Cloned natural suppressor cell lines derived from the spleens of neonatal mice

The establishment and characterization of cloned natural suppressor (NS) cell lines derived from the spleen of neonatal BALB/c mice are described. Cloned NS cells suppress the mixed leukocyte reaction (MLR) between normal adult responder and stimulator spleen cells with a 50-fold greater efficiency than fresh neonatal cells. Suppressive activity of both cells did not depend on the haplotype of the responder or stimulator cells, and was radioresistant. Cloned NS cells did not inhibit the uptake of [3H]thymidine by HT-2 cells proliferating in response to interleukin 2 (IL-2), nor the in vitro secretion of IL-1 by macrophages in response to lipopolysaccharide. Several experiments indicated that absorption of IL-2 could not explain the suppression of the MLR by the NS cells in the range of cell numbers tested. The results suggest that NS cells may suppress the MLR by interfering with early stages of T cell activation. The cell surface of a cloned NS cell line was examined using immunofluorescence staining, and was strongly positive for the Thy-1.2, Ly-5, and asialo-GM1 antigens. However, Lyt-1, Lyt-2, surface Ig, IE, MAC-1, and Fc and C3 receptor markers were not detected. In addition, NS cells showed no cytolytic activity against the YAC-1 target cell line. On the basis of these findings, cloned NS cells do not appear to be mature T cells, B cells, macrophages, or NK cells. The development of cloned NS cells may be useful in determining the identity and mechanism of action of nonspecific suppressor cells in the neonatal spleen, and their role in neonatal tolerance and maternal-fetal relationships.

Postnatal development of functional T cell subsets in the mouse: a frequency analysis of mitogen reactive precursors of proliferating, of cytotoxic and of IL 2 producing T cells

In order to study the postnatal development of functional T cell subsets in the mouse, a mitogen-driven limiting dilution culture system was used for a precursor frequency analysis of proliferating, of cytolytic and of IL 2-producing T cells, respectively, present in spleen and thymus of mice from neonatal to adult age. In adult mice, the majority (up to 100%) of splenic T cells was capable to respond to Concanavalin A. In contrast, an up to tenfold lower frequency of mitogen-reactive precursors was found within positively selected Thy-1+ spleen cells of neonatal mice. Within this fraction of Con A reactive neonatal T cells, there was an apparent imbalance in the CTLp/PTLp ratio within the first to second week after birth. Accordingly, significant numbers of immunocompetent precursors of HTLp were detected in the spleen shortly after birth, while the vast majority of CTLp developed later on. This differential development of CTLp and PTLp was not seen with thymocytes of the same mice, where from the age of two to three days on up to the adult age the frequency of both CTLp and PTLp remained largely unchanged. Analysis of the Lyt-antigen expression, in addition, revealed phenotypical differences between neonatal and adult Thy-1+ spleen cells, such that Lyt-2 antigen density but not the proportion of Lyt-2 positive T cells, was considerably lower in newborn mice. An age related increase in both Lyt-2 antigen density and CTLp frequency was parallelled by the rapid increase in the total number of splenic T cells during the second and third postnatal week, reaching 60-70% of adult values. At this time, a normalisation of the CTLp/PTLp ratio at approximately 0.4 had occurred.

Naturally occurring spleen-associated suppressor activity of the newborn mouse. Requirement for two genetic restrictions in suppression of lethal graft-versus-host disease by newborn spleen cells

Spleens from newborn mice less than 6-7 days of age are known to contain naturally occurring suppressor cells, which can suppress the immune reactivity of third-party adult cells. In the present study newborn spleen cell populations are shown to possess the potential to inhibit lethal graft-versus-host (GVH) disease in sublethally gamma-irradiated hosts injected with allogeneic adult cells. However, this capacity to suppress GVH disease is controlled by at least two genetic restrictions: (1) the newborn spleen cells and the adult donor cells must be histocompatible at an H-2-linked region apparently telomeric of H-2DL, and (2) the newborn spleen cells must express a strongly stimulating non-H-2 (perhaps M1s) alloantigenic phenotype. Host animals that survive GVH remain chimeric for at least 3-4 weeks but return to the host phenotype by 8-10 weeks. Thus, it appears that in sublethally irradiated hosts the newborn cells suppress donor cell reactivity long enough for the host system to recover from the effects of irradiation.

Ontogeny of T-cell mitogen response in Lewis rats: II. Early appearance and loss of suppressor activity

Spleen cells from rats 2 to 132 days old were cultured with 1-125 micrograms/ml Concanavalin A (Con A). At high doses of Con A, the high spontaneous thymidine uptake of spleen cells from rats 15 to 21 days old was suppressed, whereas spleen cells from younger rats showed no suppression of spontaneous mitogenesis at equally high Con A doses. Removal of either plastic-, nylon wool-, or carbonyl iron (cFe) adherent cells not only removed suppression of background by high Con A doses, but also allowed mitogenic responses at adult levels in normally unresponsive 15 to 21 day old pups. Low doses of X-irradiation did not cause a similar loss of suppression. We suggest that although there is an influx of ConA responsive cells into the rat spleens at 15 to 16 days, the mitogen responses of these cells are suppressed by an adherent cell population which is activated by high doses of Con A.

Neonatal splenic suppressor cells in the chicken. I. In vivo suppression of the immune response to bovine serum albumin by normal and tolerized neonatal spleen cells

The presence of active splenic suppressor cells in neonatal chickens, either normal or tolerant to bovine serum albumin (BSA), was examined by assessment of their effect on both primary and adoptively transferred secondary responses to BSA or sheep red blood cells (SRC). Both normal and BSA tolerized spleen cells were shown to be highly suppressive of secondary anti-BSA responses generated by specifically primed adult spleen cells in inert recipients. Suppression of the secondary anti-BSA response by normal spleen cells was slightly less effective than that seen with BSA tolerant spleen cells. Transfer of BSA tolerant spleen cells into normal recipients, followed by BSA challenge, prevented any significant primary anti-BSA response. In contrast, transfer of normal spleen cells into normal recipients, followed by BSA challenge, failed to show any suppression of the resulting primary response. Neither normal nor BSA tolerant neonatal spleen cells were capable of suppressing either primary or secondary responses to SRC. Thus, chickens tolerized to BSA have suppressor cells specific for the tolerizing antigen. We present evidence that both the tolerance associated suppressors and the suppressors detected in normal neonatal chickens are T cells.

Analysis by limiting dilution of interleukin 2-producing T cells in murine ontogeny

The ontogeny of interleukin 2 (IL 2) production in young CBA/HT6T6J mice was studied using both bulk culture and limiting dilution methods. The ability of spleen cells in bulk culture to produce IL 2 in response to concanavalin A (Con A) was found to rise through the first 2 weeks of life, from no production at day 1, through 20 units/ml at day 6, to 80-100 units/ml in adults. No evidence for suppression of IL 2 production by young spleen was found. Limiting dilution analysis of both young spleen and young lymph node (LN) shows that young spleen has a much lower complement of cells producing IL 2 in response to Con A or allogeneic stimulation than does adult spleen. The frequency of 6-day spleen cells producing IL 2 in response to Con A is 1/1000, while the adult frequency is approximately 1/50. Young LN, in contrast, has levels of IL 2-producing cells close to those of adult LN, with a frequency of responders to Con A of 1/20. No evidence was found for a deficiency in IL 2 production on a per cell basis, in either 6-day spleen or LN. In examining allogeneic reactivity, a high frequency of cells reacting to strong Mls stimulation was found in both young and adult spleen and LN.

Changes in spleen cell proliferative responses and resistance to syngeneic tumor challenge in aging NBR rats

New Zealand Black rats are shown to have a mean longevity of 102.9 weeks. The 90%, 50% and 10% survival age are 81 weeks, 108 weeks and 126 weeks, respectively. Resistance to syngeneic tumor challenge is significantly lower in young rats (3-35 weeks) and very old rats (126-140 weeks) compared to middle-aged rats (36-85 weeks). The in vitro spleen cell proliferative response to syngeneic tumor cells is decreased in old rats. No decrease is observed in spleen cell proliferation induced by the mitogens concanavalin A or phytohemagglutinin. Young (4 weeks) rat spleens contain suppressor cells which affect the mitogen and syngeneic tumor cell induced proliferation of responsive spleen cells (from 50-week-old rats). Spleen cells from old rats (130 weeks) do not demonstrate analogous suppressor cell activity.

Isolation and identification of the naturally occurring, newborn spleen-associated suppressor cells. A mixed monocyte/mast cell population with separable suppressor activities

Spleens from newborn mice less than 6-7 days of age contain 'naturally occurring' suppressor cell populations that are able to inhibit nonspecifically immune responses of third-party adult spleen cells and alloreactivity in the newborn spleen per se. Isolation of the effectors of this suppressor activity reveals that they are not classical T lymphocytes but, instead, a mixed population of cells of the monocyte series (monoblast/promonocyte/monocyte) plus mast cells. This mixed population apparently can elicit its suppressor activity in part through secretion of soluble, in vitro culture-stable material, which in turn initiates activation of the suppressor cell/limb of the immune response. These activities, nevertheless, modulate most strongly the early activation events of T-cell responses and can result in complete suppression of alloreactive helper and cytotoxic T lymphocyte development. Suppressor activity by mast cells can be demonstrated by degranulation, whereas suppressor activity by monocytes appears inherent in the newborn population. Thus, there are now at least three cell populations in the neonate spleen--mast cells, monocytes, and T lymphocytes--which can effect suppressor activity.

Spleen cells from adult mice given total lymphoid irradiation or from newborn mice have similar regulatory effects in the mixed leukocyte reaction. I. Generation of antigen-specific suppressor cells in the mixed leukocyte reaction after the addition of spleen cells from adult mice given total lymphoid irradiation

We added spleen cells from adult BALB/c mice treated with total lymphoid irradiation (TLI) to the mixed leukocyte reaction (MLR) using a variety of responder and stimulator cells. The spleen cells nonspecifically suppressed the uptake of [3H]-thymidine and the generation of cytolytic cells regardless of the responder-stimulator combination used. We also examined the effect of the spleen cells on the generation of antigen-nonspecific and antigen-specific suppressor cells in the MLR. The experimental results suggest that the spleen cells from TLI-treated mice inhibit the generation of nonspecific suppressor cells, but do not inhibit the generation of antigen-specific suppressor cells. Thus, alloantigenic stimulation of normal responder cells in vitro in the presence of spleen cells from TLI-treated mice generates large numbers of antigen-specific suppressor cells, but few cytolytic cells or nonspecific suppressor cells. Similar nonspecific inhibition of the MLR was observed with neonatal spleen cells. This in vitro system provides a regulatory model for the induction and maintenance of tolerance in vivo, in which adult mice given TLI or neonatal mice accept allogeneic bone marrow transplants without graft-vs.-host disease.

Induction of lymphoid cell chimerism in noninbred, histocompatible rabbits. A new model for studying allotype suppression in the rabbit

Noninbred rabbits, matched with regard to the major histocompatibility complex (RLA-A and RLA-D loci) but mismatched for Ig allotypes, served as donors (adult) and recipients (newborn) of lymphoid cells. Lasting chimerism regularly followed the transfer of 1 x 10(8)-3 x 10(8) spleen, lymph node, or bone marrow cells, as indicated by the continued production of Ig with allotypic determinants of both donor and recipient. Typically, Ig of donor allotype accounted for 25-50% of total allotypic Ig at 4 wk of age and the amount of donor Ig produced remained stable for up to 20 mo. Total allotypic Ig levels remained normal in the chimeric rabbits. "Chimeric drift" or a gradual diminution of donor products over a period of several months, occurred in some individuals. Transfer of lymphoid cells from allotype-suppressed adult donors to newborns of appropriate allotypes did not result in specific suppression of the target allotype in the recipients. Other experiments showed that lymphoid cells from suppressed donors adoptively transferred to histocompatible recipients continued to synthesize Ig of the nonsuppressed type only. The suitability of using an outbred population of histocompatible but allotype-mismatched rabbits for analyzing allotype suppression and other immunoregulatory phenomena is demonstrated by the results presented here.

Immunosuppressor cells from newborn mouse spleen are macrophages differentiating in vitro from monoblastic precursors

Newborn mouse spleen, whose cells strongly suppress the in vitro humoral response of adult spleen cells, is essentially a hematopoietic organ. It contains a large percentage of proliferating cells, among which about 50% are erythroblasts (identified by their spectrin content) and about 15% are cells of the myelocytic and monocytic lineage. Lymphoid cells are a minority, with about 20% B and only 1-2% T lymphocytes. After a 4 days, a culture of newborn spleen cells contains 5-10 times more macrophages than that of an adult spleen. Most of these macrophage precursors from the newborn spleen are proliferating cells, partially glass- or plastic-adherent, which differentiate in culture into activated macrophages producing large amounts of plasminogen activator. It is this macrophage excess which is responsible for the immunosuppressive effect of newborn spleen cells in culture, as indicated by (a) the effect of silica particles added to the cultures, which both relieve the suppression and prevent the accumulation of macrophages and (b) the suppression of the humoral response of adult spleen cells when they are cultured on the adherent cells from a newborn but not from an adult spleen. The suppressive effect of macrophages seems to result, at least in part, from the production of prostaglandin, since it can be relieved by indomethacin or aspirin. Suppression is not related to arginine depletion of the medium or to production of an excess of plasminogen activator. T lymphocytes from newborn spleen or lymph nodes have no suppressive capability.