Suppressor T cells derived from early postnatal murine spleen inhibit cytotoxic T-cell responses

Postnatal T-suppressor cells have been detected in a number of experimental systems. They have been shown to inhibit humoral responses, proliferation in a mixed-lymphocyte reaction and the induction of killer cells. The suppressor function observed in the postnatal mouse does not appear to be antigen specific and its ontogeny may be influenced by other cell types and by serum factors such as α-fetoprotein. We have detected a nonadherent, radioresistant splenic T cell present in neonatal mice ranging in age from 1 to 9 days which can nonspecifically suppress killer cell induction. This suppressor cell must be cultured in vitro in order to function, but it does not require alloantigen to be induced. Adult spleen cells tested in the same system yield antigen-specific T-cell suppression. Our results suggest that the nonspecific suppressor detectable in 1- to 9-day-old mice disappears in adult life, and is replaced by antigen-specific suppressors. The biological role of these suppressors is discussed.     

IL-1 secretion and membrane IL-1 expression by neonatal spleen cells during soluble antigen presentation

Antigen presentation and IL-1 production by neonatal spleen cells were studied in a murine model. The T-helper-cell line (D10-G4.1) (D10), which is specific for soluble antigen presented on syngeneic antigen-presenting cells and dependent on IL-1 for its proliferation, was used as an indicator cell for the ability of syngeneic neonatal or adult spleen cells to present antigen and produce IL-1. The antigen-presenting capacity of neonatal spleen cells is low as attested by D10 proliferation. During antigen presentation there is an augmentation of IL-1 production by the antigen-presenting spleen cell population. However, neonatal spleen cells do not respond to the same levels as do adult spleen cells. These reduced levels of secreted IL-1 cannot be attributed to a low potential for producing IL-1 as attested by the high levels of IL-1 made by these cells after induction by a crude IL-1 inducer factor (IL-1-IF) and by the stimulus of the IL-1-IF produced by D10 cells during antigen presentation by paraformaldehyde-fixed adult cells. The spontaneous expression of membrane IL-1 by neonatal cells is low. Membrane IL-1 levels on neonatal cells can be brought to adult levels by induction with IL-1-IF. Neonatal spleen cells have an impaired capacity to process and/or present soluble antigen. This impairment leads to a decreased stimulus of the T helper cell to produce inducer factors and thus a reduced level of IL-1 production by the neonatal cells during antigen presentation.     

Responsiveness of Thymus Cells to Syngeneic and Allogeneic Lymphoid Cells

THE thymus is necessary for the normal development of cell-mediated immunity in mice as shown by the immunological defects after neonatal thymectomy¹. Thymus cells themselves can be stimulated by allogeneic lymphoid cells in mixed leucocyte reaction (MLR)² and become killer cells or cytotoxic lymphocytes after stimulation with allogeneic spleen cells in vitro (H. Wagner and M. Feldmann, unpublished work) and in vivo^3,4. This suggests that the thymus as well as peripheral lymphoid tissues contain T cells which can be stimulated by foreign histocompatibility antigen to divide and differentiate into the cytotoxic lymphocytes which mediate cellular immunity. There have been suggestions that thymus cells might be stimulated to divide by “self” antigen, as well as foreign cells: incorporation of ³H-thymidine above background levels has been found in cultures with syngeneic spleen and thymus cells of adult rats⁵, although the experiments do not determine whether thymus or spleen cells have been stimulated. In contrast to these experiments, Howe et al. reported that only thymus cells of neonatal CBA mice reacted to allogeneic and syngeneic spleen cells of adult animals in “one way” MLR cultures^6,7. Whether the reaction of neonatal thymus cells to syngeneic adult spleen cells is recognition of “self” antigens is uncertain, since spleens of adult mice could carry antigens which do not occur in neonatal animals and are therefore “unknown” for neonatal thymus cells. We demonstrate here that neonatal thymus cells do not react to 4-day-old CBA spleen cells, but adult thymus cells do react against both allogeneic and syngeneic adult spleen cells.     

Development of self-tolerance in normal mice. Appearance of suppressor cells that maintain adult self-tolerance follows the neonatal autoantibody response

T cell populations from BALB/c mice at different ages were analyzed to determine when in development Ts cells specific for the anti-mouse RBC (MRBC) autoantibody response become activated. Previous studies have shown that adult CD8+ T cells actively suppress this autoimmune response and adult spleen cells depleted of CD8+ cells can generate an anti-MRBC response in culture with MRBC. The present results demonstrate that T cells from mice less than 1 wk of age do not suppress the in vitro anti-MRBC response of adult spleen cell populations depleted of CD8+ Ts cells. By 2 wk of age Ts cells are detectable in this anti-self response and reach adult levels by 3 wk of age. Non-specific "natural suppressor" cells normally present in neonatal spleen cell populations are unable to suppress this autoantibody response, although they are active in suppressing anti-SRBC responses in the same cultures. Before the appearance of Ts cells active in the anti-MRBC response, neonatal spleen cell populations can generate anti-MRBC antibody-forming cells, both spontaneously in vivo and in vitro. The in vitro anti-MRBC response of neonatal spleen cells was shown to be Ag driven and Ag specific. The ability of unfractionated spleen cells to generate this response in vitro declines with age and is relatively low by 3 wk. This decline in responsiveness occurs simultaneously with the appearance of suppression specific for the anti-MRBC response, suggesting that the two events may be causally related.     

Novel immunoregulatory functions of phenotypically distinct subpopulations of CD4+ cells in the human neonate.

Although normal numbers of CD4+ T cells are present in the human neonate, cord blood CD4+ cells are deficient in their ability to provide help for antibody production. In the present studies, we have examined the cellular basis for this functional deficit by analyzing the phenotypic properties and immunoregulatory functions of the subsets of cord blood CD4+ cells defined by anti-CD45RA mAb. In contrast to CD4+ cells from adults, greater than 90% of cord blood CD4+ cells expressed the CD45RA, CD38, and Leu-8 membrane Ag. When neonatal CD4+ cells were cultured with adult B cells and PWM or anti-CD4+ mAb, no helper function was apparent. However, when the small number of CD4+CD45RA- cells in cord blood were purified and similarly analyzed, helper activity comparable to that of adult CD4+CD45RA- cells was found. This helper function was profoundly suppressed by the presence of even small numbers of cord blood (but not adult) CD4+CD45RA+ cells. Irradiation of mitomycin C treatment of neonatal CD4+CD45RA+ cells abrogated their suppressor activity, but did not induce helper capability. However, after activation with PHA and culture in IL-2, cord blood CD4+CD45RA+ cells lost their suppressor activity and acquired the ability to provide help for B cell differentiation. This functional maturation was accompanied by their conversion to the CD4+CD45RA- phenotype. Thus, whereas cord blood CD4+CD45RA+ and CD4+CD45RA- cells share certain properties with the analogous subsets in adults, our data show that the dominant immunoregulatory function of cord blood CD4+ cells is suppression mediated by CD4+CD45RA+ (and CD38+) cells. In view of these phenotypic and functional differences between neonatal and adult CD4+CD45RA+ cells, we propose that "naive" CD4+CD45RA+ cells undergo age-related maturational changes that are unrelated to their postulated activation-dependent post-thymic differentiation into CD4+CD45RA- "memory" cells capable of helper functions.     

Spleen cells from athymic mice are ineffective stimulator cells for cytotoxic responses in microcultures and in vivo

The stimulator cells for the activation of cytotoxic T lymphocyte (CTL) precursor cells were studied in vivo and in microculture systems with limiting concentrations of helper factor (interleukin-2). We found in both cases that mixtures of irradiated spleen cells from athymic and euthymic donors of different haplotypes activated CTL responses preferentially against alloantigens which were carried by the euthymic donors. This applied also if athymic and euthymic donors shared parts of the H-2 gene complex. Stimulator cells from athymic and euthymic donors activated, on the other hand, equally strong responses in microcultures which were supplemented with additional helper factor or in conventional macrocultures. This and direct cell mixing experiments showed that the ineffective stimulation by the nude spleen cells in vivo and under conditions of limiting helper factor was not mediated by active suppression. Our experiments are therefore best explained by the assumption that cytotoxic responses under conditions of limiting helper factor require a close proximity between CTL precursor cells and helper T cells. This proximity may be most efficiently provided by the receptors of the CTL precursor cells when helper T cells serve as stimulator cells. Lymph node cells were consistently inferior to spleen cells as stimulator cells, and the nylon wool nonadherent fraction of spleen cells was on the average also inferior to unfractionated spleen cells, indicating that the stimulator T cells belong to a spleen seeking and partly nylon wool adherent T-cell subpopulation or require an additional cell type for optimal stimulation.     

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.     

Soluble suppressor activity of concanavalin A-activated spleen cells on B-lymphocyte colony formation in vitro.

Supernates from concanavalin A (Con A)-activated mouse spleen cell cultures suppress the formation of B-lymphocyte colonies (BLC) in soft agar culture by 30 to 95%. Con A-induced BLC suppressive culture supernates can be heated at 80 °C for 1 hr without losing activity. The BLC suppressive activity is eliminated totally by trypsin treatment and partly by treatment with β-galactosidase. Activity is unaffected by treatment with DNAse, RNAse, and α-glucosidase. By ultrafiltration the BLC suppressive factor(s) was shown to have a molecular weight greater than 300,000. These data suggest that BLC suppression is mediated by a protein-carbohydrate complex. BLC suppression was obtained when normal spleen cells were preincubated in Con A-activated supernates for only 1 hr at 37 °C. BLC suppressor activity was absent in the supernatant fluid of Con A exposed anti-θ-treated spleen cells, nonadherent spleen cells, extensively washed spleen cells, and spleen cells from nude (athymic) mice suggesting that cells responsible for Con A-induced BLC suppression are adherent, fragile cells of the T lineage. Con A-activated spleen cell supernates do not suppress colony formation in soft agar by normal mouse granulocyte-macrophage precursors, by plasmacytoma cells, T-lymphoma cells, or by carcinoma cells. However, colony formation by Abelson's murine leukemia virus transformed B-lymphoma cells was suppressed by 95% suggesting a relationship between this immature B-lymphoma line and B-lymphocyte colony-forming cells. Con A-activated spleen cell supernates do not suppress lymphocyte activation in liquid culture by phytohemagglutinin, Con A, or lipopolysaccharide. Heat-treated supernates—which inhibited BLC development by 90–95%—did not suppress the plaque formation by spleen cells immunized in vivo or in vitro by sheep red blood cells.     

Effect of concanavalin A treatment on the allogeneic response of mice to challenge with P 815 mastocytoma: interleukin 2 treatment reverses concanavalin A suppression in vivo

Mice injected repeatedly with concanavalin A (Con A) prior to and following challenge with P 815 mastocytoma are suppressed in their cell-mediated cytotoxicity responses. Earlier studies showed that pretreatment of the animals with silica to affect macrophage (M phi) functions reversed the Con A suppression. In the present paper we have shown that peritoneal exudate cells (PEC) induced/activated by ip injection of Con A were able to transfer suppression to normal mice. Separation of the PEC populations into adherent and nonadherent cells abrogated their capacity to transfer suppression. It was further shown that Con A is not functioning in this in vivo system to block effector activity of cytotoxic cells on target cells, and PEC induced with Con A were not directly cytotoxic to target P 815 cells. Finally, we were able to show that the cytotoxicity response of Con A-suppressed mice could be enhanced by treatment with concentrated culture supernatants of normal mouse spleen cells, rich in interleukin 2 (IL 2) activity. Attempts to detect a recently described mouse serum inhibitor of IL 2 in normal or Con A-treated mice were unsuccessful and spleen cells from Con A-treated mice lost their capacity to generate IL 2 in vitro when cultured under appropriate conditions. Taken together, these results suggest that suppression of cell-mediated immune responses in Con A-treated mice results from interruption of the normal generation of IL 2 helper effects necessary for the activation of cytotoxic effector T cells in vivo.     

Thymus-dependent suppression of erythroid colony formation induced by concanavalin A in the cloning of pluripotent hematopoietic stem cells of the spleen

The injection of the polyclonal activator of T-cells--concanavalin A--to normal mice is followed by a considerable decrease both in the erythroid colony-formation at the cloning of spleen CFUs, and in the number of T-cells and their helper activity in the same spleen suspensions. The suppression of erythroid colony-formation may be passively transferred by using spleen cells from mice treated with concanavalin A and irradiated lethally. Thymectomy of adult mice prevents from suppression of erythroid colony-formation induced by concanavalin A. These results suggest that the T-cells may suppress erythroid differentiation of hemopoietic stem cells.     

Nature of neonatal splenic suppressor cells in the mouse

Due to the controversy in the recent literature concerning the T-cell nature of the neonatal mouse splenic suppressor cell, we have reexamined the nature of these cells at different stages after birth. With the use of monoclonal anti-Thy antibody we can detect T-cell products on spleen suppressor cells from BDF₁ mice at 3, 4, 5, 6, and 7 days of age. The suppressor cells are assayed by their ability to inhibit mixed-lymphocyte reactivity, which is an in vitro example of cell-mediated immunity. The neonatal spleen suppressor cells also carry products of the Ly 1 and I-J locus. Neonatal thymectomy results in a premature decrease of suppressor cell activity. These data suggest that the mouse neonatal splenic suppressor cell is a short-lived Ly 1⁺, I-J⁺ T cell.     

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.     

An analysis of B cell memory. I. Interaction of helper and suppressor effects in the in vitro expression of IgM memory.

The pfc response of Srbc primed IgM memory cells has been characterized by limiting dilution analysis in vitro, in which LPS was used to maximize the response of spleen cells to Srbc. The analysis suggested that, even under these conditions, expression of B cell memory was not directly assayed and cell collaboration effects were still basic to the system.Two types of cells, as defined by function, appeared necessary to elicit optimal clonal proliferation of IgM B memory cells: firstly, helper T cells were essential for B cell proliferation even with LPS present in culture. Under appropriate conditions, helper activity could be provided by normal thymus cells. Secondly, activated T cells were required for the maximal conversion of normal thymus cells to helper cells. A third activity, T cell-dependent suppression, was observed at high cell doses. The implications of these results and the need for a comprehensive analysis of in vitro conditions for each individual type of experiment is discussed.     

Nude mice--a model system for studying the cellular basis of the humoral immune response

Mice homozygous for the nu gene fail to develop a thymus. In comparison to spleen cells from +/nu mice spleen cells from nu/nu mice have a deficient 19S PFC response to SRBC when tested in culture or in vivo. This deficiency is due to a lack of “helper” T cells in nu/nu spleen; A cells and B cells appear to be normal. The capacity of nu/nu spleen cells to produce a PFC response in culture can be corrected by the addition of T cells obtained from either the thymuses or the spleens of +/nu mice. In contrast to “helper” T cells obtained from the spleen, “helper” T cells obtained from the thymus appear to require the capacity for proliferation during the response to SRBC.     

Effect of passive administration of alloantiserum containing antibody against putative acceptor(s) for T cell-replacing factor (TRF) in the neonatal stage on development of B cell activity responsive to TRF

Previously, we showed that the antiserum raised in male (DBA/2Ha X BALB/c)F1(DCF1) mice (T cell-replacing factor [TRF]-low response animals) by immunizing them with activated B cells from BALB/c mice (TRF-high-responders) contained antibodies against putative TRF-acceptor site(s). We have now evaluated the hypothesis that neonatal treatment of mice with the above antiserum suppresses the development of B cells responsive to TRF. Male DCF1 mouse anti-BALB/c B-cell antiserum or normal DCF1 mouse serum as a control was injected into BALB/c mice within 24 hr after birth. In the antiserum-treated mice, no augmented primary immunoglobulin M (IgM) antibody responses to sheep red blood cells (SRBC) were observed under the conditions in which markedly augmented IgM anti-SRBC responses were induced in control BALB/c mice, suggesting that development of B cells reacting with male DCF1 mouse anti-BALB/c B-cell antiserum is suppressed by the neonatal treatment with the antiserum. Furthermore, the development of B cell activity responsible for helper factors derived from T cells, such as TRF, was markedly suppressed in the neonatally antiserum-treated mice, whereas activity of B cells capable of interacting directly with helper T cells through antigen-bridges was not significantly affected by the same treatment. Such suppression of the B cell activity could be induced only when the antiserum was administered within 48 hr after birth. Moreover, neonatal treatment of mice with the antiserum induced suppressed responsiveness of B cells to a T-independent type 2 antigen, TNP-Ficoll. Neither serum-borne suppressive serum components nor suppressor cells were detected by the system employed. These results support the hypothesis that TRF responsive B cells constitute a subpopulation distinct from the other B cells capable of cooperating with helper T cells via cognate interaction.     

Natural suppressor (NS) activity from murine neonatal spleen is responsive to IFN-gamma

Natural suppressor (NS) cell activity is the ability of apparently unprimed "null" cells to nonspecifically suppress immune responses. Previously we have shown that NS cell activity from the spleens of mice undergoing chronic graft-vs-host disease (GVHD) is enhanced in vitro by activated T cell signals (e.g., Con A supernatant [CAS]). Here we asked if the naturally occurring suppressor activity found in the neonatal mouse spleen is caused by NS cells, and if so whether this NS activity is also responsive to T cell signals. Finally, we wanted to identify the material in the CAS to which the NS cells respond. Spleen cells from (BALB/c X B10.D2)F1 neonates contain potent, genetically unrestricted suppressor activity toward normal mitogen responses. The cells responsible for this suppression are nonadherent, Thy-, Ig- and are thus by definition NS cells. Neonatal spleen NS cells suppress the indicator Con A response of all mouse strains tested, but their behavior with regard to LPS responses is different. They significantly inhibit the indicator LPS response of allogeneic strains, but are less inhibitory of LPS-stimulated syngeneic (BALB/c X B10.D2)F1 and parental strains. However, the addition of CAS to these latter cultures enhances the NS inhibition of the LPS response to the level of suppression seen with a Con A response. Two lymphokines were able to replace the CAS. Recombinant interferon-gamma (rIFN-gamma) closely mimics the activity found with whole CAS, with low concentrations (1 U/well) being capable of enhancing the neonatal NS activity to near-maximal levels. Recombinant interleukin 2 (rIL 2) is also capable of stimulating the neonatal NS activity to near maximum. However, the rIL 2 must be added at much higher concentrations, taking greater than 50 U/well to get maximum activation of NS suppression. The addition of anti-IFN-gamma antiserum to these LPS suppression assays removes the ability of CAS to activate the neonatal NS cells. Anti-IFN-gamma antiserum also removes the ability of rIL 2 as well as rIFN-gamma to activate the NS cells. It thus appears that the rIL 2 is working by its ability to stimulate IFN-gamma production. Anti-IFN-gamma also removes the ability of the neonatal NS cells to suppress a Con A response. Therefore, it appears that neonatal splenic NS cells respond to, and are activated by, IFN-gamma to carry out their suppressive activity.(ABSTRACT TRUNCATED AT 400 WORDS)     

Role of I-J in neonatal suppression

Spleen cells from neonatal mice belonging to strains with the I-J-b or I-J-k genotype, were treated with anti-I-Jb or anti-I-Jk antibody and complement. This reduces their suppressor cell activity as demonstrated by a decrease in the ability to suppress the mixed-lymphocyte reactivity of adult spleen cells. Injection of anti-I-J antibody into neonatal mice also reduces splenic suppressor cell activity prematurely. The removal of suppressor cells from neonatal spleen does not result in an immediate increase in mixed-lymphocyte reactivity (cell-mediated immunity) but does hasten the development of mixed-lymphocyte reactivity in the young mice. The results are discussed in light of the hypothesis that suppressor cells inhibit the function of immunocompetent cells in the neonatal mouse and control the development of immunocompetence.     

Regulation on murine T cell responses to autologous antigens by alpha-fetoprotein

Murine α-fetoprotein (AFP), a major component of fetal and newborn sera, was shown to exert potent immunosuppressive effects on autologous mixed lymphocyte reactions (AMLR) in vitro. Thus, the relatively vigorous proliferative response of newborn CBA/J thymocytes reacting in mixed cultures against adult syngeneic spleen cells was almost totally abrogated by 200 and 100 μg/ml AFP over the 6-day time course studied, with significant suppression still evident in the presence of 10 μg/ml AFP. In contrast, the maximum achievable suppression of parellel allogeneic MLRs was only 40 to 60%. The newborn thymocyte anti-adult syngeneic spleen AMLR was shown to be mediated by an Lyt 1⁺23^? T-cell subset reacting against Ia⁺ adult non-T stimulator cells. Newborn and adult AMLRs resulting from autochthonous T responder/non-T stimulator cell mixtures from individual animals were also found to be highly sensitive to AFP-mediated suppression. The fact that fetal-derived AFP could be shown to efficiently inhibit neonatal thymocyte responses to autologous antigens when tested in vitro in amounts 20 to 50 times lower than the levels present in fetal and newborn sera suggests a potentially important role for endogenous AFP in the regulation of autosensitization during ontogeny.     

Suppressor factor produced by neonatal mouse spleen cells

Spleen cells from 5- to 6-day- old BDF₁ mice produce a soluble suppressor factor (SF) when cultured for 2–4 days in the presence of 10% fetal calf serum. This suppressor factor inhibits the mixed lymphocyte reactivity of adult mouse spleen cells as well as the in vitro generation of cytotoxic cells. The SF which is not H₂-restricted or antigen specific is most effective when added in the early phase of the culture period. The SF is resistant to heat and uv treatment and appears to consist of a large and small component. It is resistant to treatment with pronase or trypsin. The SF appears to be produced by neonatal spleen cells which are not adherent to plastic or Sephadex G-10 and are insensitive to treatment with anti-Thy 1.2 and complement. Incubation of SF with peritoneal exudate cells reduces suppressor activity.     

Appearance of lymphocyte surface markers and functional responses in neonatal and young rabbit spleens

We examined spleen cells from newborn to 1-month-old rabbits for easily detectable surface immunoglobulin, complement receptors, and for in vitro proliferative responsiveness to anti-immunoglobulin antisera and several mitogens. From birth through the first month of life about 15% of the cells from rabbit spleens had easily detectable surface immunoglobulin while about 45% had C3 receptors. In adults as many as 77% of the spleen cells had easily detectable surface Ig but the proportion with C3 receptors remained about 45%. The proliferative response to anti-allotype antisera was present at birth, and was at adult levels by 1 month of age. The proliferative response to pokeweed mitogen was low when cells were obtained during the first week of life but was comparable in magnitude to the response of adult cells by 2 weeks of age. In vitro responsiveness to concanavalin A was present at low levels at birth and increased sharply during the first week. We did not observe significant stimulation of spleen cells from neonatal to 4-week-old rabbits by lipopolysaccharide from Salmonella typhosa. Our data suggest that lymphocyte surface markers and functional responses appear asynchronously in spleen cells of developing rabbits.