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.     

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)     

Demonstration of active suppressor cells in spleens of young NZB mice

NZB mice, a strain prone to the development of autoimmune disease, have during the first 2 weeks of life suppressor cells in their spleens which can in coculture with adult spleen cells suppress the antibody response to sheep red blood cells (SRBC) generated in culture by the adult cells. The suppressive activity of spleen cells from NZB mice in the first week after birth is similar to that of spleen cells from 4-day-old C57BL/6 mice, a strain which does not spontaneously develop autoimmune disease. As in “normal” strains of mice, suppressor cell activity in NZB mice is diminished at 2 weeks and undetectable at 3 weeks of age. The data indicate that there is no defect inherent in the suppressor cells detected in the spleens of newborn and young NZB mice and suggest that the development of autoimmune responses does not result from a lack of suppressor cells in the young animals.     

Further characterization of murine bone marrow-derived natural suppressor cells. Potential relationships between NS and NK/LAK activities

Murine bone marrow (BM) cells regulate a variety of immune responses via an endogenous natural suppressor (NS) activity. We demonstrate that BM-derived NS activity resides in an enriched fraction of large, low-density cells which have a high proliferative rate. Complement-dependent lysis of BM cells by antibody directed against markers of Veto and NK/LAK cells had no effect on NS activity. The BM of SCID mice and their littermate C.B-17 possessed normal NS activity. Conversely, the BM of NK-deficient C57 beige mice displayed reduced NS activity as compared to normal C57 black mice. Long-term BM cultures (LTBMC) generated in medium containing supernatants of Con A-stimulated (CAS) rat spleen cells resulted in the emergence of a population of cells which possessed NS activity greater than that of fresh BM cells. The LTBMC were also potent effectors of NK activity, as compared to fresh BM, which had little NK activity. Thus, while NS, NK/LAK, and Veto cells are all nonspecific effectors of immune suppression, the exact relationship between them is not clear.     

Recognition specificities, development, and possible biological function of natural killer cells in the mouse. I. Spleen focus forming assay for natural killer activity and analysis of lectin-like recognition structures on the surface of murine natural killer cells

A number of simple sugars have been tested and found to be effective in blocking lysis of YAC-1 tumor target cells by nonimmune murine natural killer (NK) effector cells. Using a spleen fragment culture system an assay has been developed which allows us to compare the inhibition of lysis observed in replicate culture wells prepared from cells contained in one spleen fragment (less than or equal to 1 X 10(6) cells). The inhibition pattern of any well was found to fall naturally into 1 of 25 (of the total 128 possible tested) patterns. Using this panel analysis of NK activity in individual mice of the same or different strain has been compared. Our data suggest that within any given strain the inhibition pattern of NK effector cells is quite uniform. Consistent differences are seen between strains which are interpreted in terms of a genetic control of the final expression of the NK recognition repertoire. In adult F1 hybrid individuals the pattern of recognition by NK cells is best considered a result of the codominant expression of genes contributed by each parent.     

Effect of stem cell mobilization with cyclophosphamide plus granulocyte colony-stimulating factor on morphology of haematopoietic organs in mice

Both granulocyte colony-stimulating factor (G-CSF) and cyclophosphamide (CY) are employed in the clinic as mobilizing agents to stimulate the egress of haematopoietic stem/progenitor cells (HSPC) from bone marrow (BM) into peripheral blood (PB). However, although both compounds are effective, the simultaneous administration of G-CSF + CY allows for optimal mobilization. The aim of this study was to compare morphological changes in major haematopoietic organs in mice mobilized by G-CSF + CY. We employed the standard G-CSF + CY mobilization protocol, in which mice were injected at day 0 with a single dose of CY followed by daily injection of G-CSF for 6 consecutive days. We noticed that the cytoreductive effect of CY on BM and spleen tissue was compensated at day 2 by the pro-proliferative effect of G-CSF. Furthermore, as evidenced by histological examination of BM sections at day 4, egress of haematopoietic cells from BM was accelerated by 2 days as compared to mobilization by G-CSF or CY alone; also, by day 6 there was accumulation of early haematopoietic (Thy-l(low) c-kit+) cells in the spleens and livers of mobilized animals. This implies that HSPC that are mobilized from BM and circulate in PB may 'home' to peripheral organs. We envision that such an accumulation of these cells in the spleen (which is a major haematopoietic organ in mouse) allows them to participate in haematopoietic reconstitution. Their homing to other sites (for example the liver) is evidence that BM-derived stem cells are playing a pivotal role in organ/tissue regeneration. The potential involvement of major chemoattractants for stem cells, like stromal-derived factor-1 which is induced by CY in various regenerating organs such as the liver, requires further study. We conclude that inclusion of CY into mobilization protocols on the one hand efficiently increases the egress of HSPC from the BM, but on the other hand may lead to the relocation of BM stem cell pools to peripheral tissues.     

Differences in the age-dependent release of a low molecular weight suppressor (LMWS) and stimulators by normal and nzb/w lymphoid organs.

The age-dependent release of soluble suppressors and stimulators of DNA synthesis by cultured thymocytes and spleen cells from C57BL/6 and BALB/c mice was compared with their release by NZB/W lymphoid organs. Spleen cells from the normal strains released high levels of suppressor early in life and gradually decresing quantities with age, NZB/W spleen cells exhibited an early deficiency followed by a later excess in the production of suppressor. These differences were quantitated by dose-response studies. Thymocytes from the normal strains released stimulatory factors throughout life. In contrast, NZB/W thymocytes stopped releasing stimulatory activity and began to produce suppressor after 2 1/2 to 4 months of life. This abnormal elaboration of suppressor by thymocytes occurred 2 months before its reappearance in the autologous spleen cell supernatant. Both the early and late-appearing (less than 1000). This activity was designed as low molecular weight suppressor (LMWS). Its aberrant production by their reported functional immunologic abnormalities. The following items were discussed: the production of LMWS by adherent spleen cells, its relationship to previously described regulators, its partial purification and initial chemical characterization, and exclusion of the naturally occurring inhibitors of lymphocyte activation, cortisol, corticosterone, cold thymidine, and cyclic AMP as the active molecule.     

Inability of newborns' or pregnant women's monocytes to suppress pokeweed mitogen-induced responses

Although an excess of human adult blood adherent cells inhibits the pokeweed mitogen- (PWM) induced normal adult lymphocyte proliferation and B cell maturation into immunoglobulin-containing cells (ICC), adherent cells collected from newborn infants or pregnant women at time of delivery were unable to exert a similar suppressor activity. After activation by Concanavalin A (Con A), newborns' and pregnant women's adherent cells acquired a suppressor activity comparable to that of control adult adherent cells. The adherent suppressor cell was shown to be radioresistant (3000 rad), indicating its probable monocytic origin. Both monocyte-suppressor activities (MSA) observed in adulthood (spontaneously) and in the neonatal period (after activation) were dependent on prostaglandin E2 (PGE2) secretion, because they were abolished by indomethacin or a specific anti-PGE2 antiserum. Expression of MSA appeared to be under a negative regulation exerted by naturally occurring T suppressor lymphocytes present in the blood of newborns or pregnant women, because incubation of adult monocytes or Con A-activated newborn monocytes with newborns' or pregnant women's T lymphocytes resulted in a dramatic decrease of their MSA. These results strongly suggest that the lack of MSA in the neonatal period and in late pregnancy is a consequence of activation of T suppressor lymphocytes.     

The effect of cyclophosphamide and gamma irradiation on adenosine deaminase and purine nucleoside phosphorylase in mice

Changes in ADA and PNP activities in the spleens and thymuses of mice were studied after a single administration of cyclophosphamide (CY, 200 mg/kg) and after whole-body gamma irradiation (5.5 Gy), applied alone or three days after CY application. In the first days after the treatment the enzyme activities were significantly depressed (p less than 0.01) with the exception of ADA in the spleen, where a high elevation (220-380%) in relation to controls was observed. During the regeneration period a pronounced rise of PNP activity in the spleen occurred mainly after a combined application of CY and irradiation (270%). In the thymus the regeneration was manifested by a mild increase of both ADA and PNP activities towards control values. The findings suggest that the expressive changes of ADA and PNP activities, participating in the purine salvage pathway, may, after a cytotoxic treatment, influence the nucleotide pool and DNA synthesis in lymphoid organs.     

The immunomodulation of the natural killer activity of the splenocytes in C3HA mice during hepatoma 22a growth

A single injection of C3HA mice with various immunomodulators-ds-RNA, thymogene (TM) and cyclophosphamide (CY)--performed one day before transplantation of syngeneic hepatoma 22a cells led to a decrease in the tumor growth rate. The most prominent effect was found following the CY treatment. The NK cell activity estimated per spleen of mice treated with ds-RNA and TM was seen increased in comparison with the control mice not given the modulators. The rate of tumor growth was due probably to this fact. The protective effect of CY may be accounted for by a direct action of this agent on tumor cells.     

lack of suppressor cell activity for natural killer cells in infant, aged and a low responder strain of mice

We have examined the reported role of suppressor cells in the regulation of NK activity in mice with naturally low NK activity (infant and aged (C57 X A)F1 hybrids (CAF1) and low responder strain AKR mice). Possible suppressor activity was assayed by mixing, at a 1 : 1 ratio, spleen cells from low activity mice with spleen effector cells from normally active 8 to 10 wk old CAF1 mice. The lytic activity of the mixture was compared with the activity of effector cells diluted with medium alone or diluted 1 : 1 with "non-suppressor" population which served as a control for nonspecific decreases in lysis. The control or "filler" cells employed were suspensions of adult CAF1 thymus, thymus from adult mice exposed to 2,000 R, and adult CAF1 spleen cells cultured for 24 hours, a procedure that depleted NK activity. In no case was the activity observed in the presumed suppressor-effector mixture significantly lower than that observed in the filler-effector cell mixtures. Thus, in infant (1 to 2 wk) and aged (12 to 18 mo) CAF1 mice and in 8 to 10 wk old AKR mice, we found no evidence for specific cell-mediated suppression of natural cytotoxicity.     

Cell cycle analysis of lymphocyte activation in normal and autoimmune strains of mice

The spontaneous spleen cell proliferation and the proliferation induced by in vivo or in vitro stimulation with such polyclonal B cell activators (PBA) as LPS, poly rI.rC, and anti-mu were studied in normal and autoimmune mice. The various murine models of autoimmunity differ in the level of naturally occurring splenic cellular hyperactivity as well as in the ability of their spleen cells to be further stimulated in vitro by polyclonal stimulators. Both the NZB strain and the MRL/Ipr strain had markedly increased numbers and percentages of spontaneously proliferating spleen cells, whereas the BXSB strain did not. Nonautoimmune strains were found to have very small numbers of activated cells in the spleen. However, such normal strains could be induced in vivo to mimic the natural splenic hyperactivity observed in older NZB and MRL/Ipr autoimmune strains by the injection of polyclonal B lymphocyte stimulators. In contrast, old hyperactive NZB mice were not further induced to undergo proliferation by in vivo administration of such stimulators. Density-separated, T depleted, spleen cells of normal and autoimmune mice were stimulated in vitro with PBA in 48-hr cultures. Cells from old MRL/Ipr and NZB mice were abnormal in both the anti-mu response and the LPS response; BXSB mice had normal anti-mu responses. These studies suggest that there is no prerequisite for spontaneous splenic hyperactivity in the development of autoimmunity. In addition, different PBA stimulate separate subsets of B cells that differ in their state of activation in the various autoimmune strains. Finally, different B cell subsets appear to be abnormal in different types of autoimmune mice.     

A syngeneic splenic cell antigen induces a suppressor T cell in lymph nodes that controls cytotoxic T-cell and primary antibody responses

The nonspecific suppression of immunological responses that is generated within host popliteal lymph nodes upon exposure to syngeneic normal spleen cells has been examined. The suppression, which had previously been described as being capable of preventing initiation of cytotoxic T lymphocytes (CTLs) to hapten-altered self antigens, arises within 3 to 7 days after injecting the spleen cells. Suppression was shown to be attributable to an induced T cell that was functional when transferred intravenously. Although the cell surface marker(s) on both splenic B and T cells that stimulates appearance of Ts has not yet been identified, the cells possessing the marker were not required to be viable to cause the induction. We have shown here that the Ts is fully functional when it is put in the antigenic site used for CTL immunization. The induced Ts has been identified as bearing the Lyt 2.1 cell surface marker. Furthermore, it has been shown to be insensitive to cyclophosphamide (CY), thus differentiating it from the naturally occurring Ts cell (TS0) that is known to be CY sensitive. In addition to preventing induction of CTLs toward hapten-altered self antigens, exposing popliteal lymph nodes to syngeneic spleen cells induced Ts capable of suppressing the primary IgM antibody response to sheep red blood cells. The Ts cells that suppressed the primary antibody response possessed the same Lyt cell surface markers and CY insensitivity as the Ts that mediated suppression of the CTL response. Thus, evidence that two dissimilar immunological reactions may be down-regulated by the same suppressor mechanism has been provided. Results of a kinetic study showed that the Ts prevented development of both the humoral and the cell-mediated immune responses by affecting their inductive phases. Possible targets for suppression that more than likely would have to be common to the two widely different immune responses have been indicated.     

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

Spleen cells from newborn BALB/c mice were added to the mixed leukocyte reaction (MLR) between a variety of responder and stimulator cells. The newborn cells nonspecifically suppressed the uptake of (3H)-thymidine and the generation of cytolytic cells regardless of the responder-stimulator combination used. Suppressor cell activity fell rapidly during the first 4 days after birth, and could not be detected by day 20. Newborn spleen cells inhibited the generation of nonspecific suppressor cells during the MLR but did not inhibit the generation of antigen-specific suppressor cells. Thus, newborn spleen cells exhibit a pattern of regulation of the MLR similar to that reported previously for spleen cells from adult mice given total lymphoid irradiation (TLI). These regulatory interactions provide a model that explains the ease of induction of transplantation tolerance in vivo in newborn mice and in TLI-treated adult mice.     

Comparison of Virulence between Seoul Virus Strain SR-11 and Hantaan Virus Strain 76–118 of Hantaviruses in Newborn Mice

Virulence of hantavirus strain of SR-11 Seoul virus and Hantaan 76–118 (HTN) of Hantaan virus were compared. Infections of both strains were lethal in newborn mice. However, inoculum required to cause lethal infection was about 4,000 times higher for strain HTN (1.65 × 10³ PFU/mouse/LD₅₀) than for strain SR-11 (0.36 PFU). Thus, both strains were considered pathogenic to newborn mice but they possessed different levels of virulence. The assay system used for these strains in newborn mice proved to be useful in the study of hantavirus vilurence. Growth curves of the two strains in CV-7 cell cultures were compared. Strain SR-11 was shown to have higher activity of virus replication and virus release into the culture fluids than strain HTN. The possibility of a relationship between replication activity and high levels of virulence in mice was suggested.     

IL-3, IL-4, and IL-6 enhance IFN-gamma-dependent bone marrow natural suppressor activity

The ability of murine bone marrow (BM) natural suppressor (NS) cells to suppress a Con A proliferation assay was greatly enhanced by supernatant obtained from the T cell hybridoma D9C1.12.17. Of the lymphokines produced by this hybridoma, three were found to enhance suppression: interleukin-3 (IL-3), IL-4, and IL-6. These molecules enhanced suppression of both unirradiated and irradiated (2000 R) BM cells indicating that augmented suppression was not just due to proliferation of NS cells. The ability of all three of the lymphokines to enhance BM suppression could be blocked by anti-interferon-gamma (IFN-gamma) antibody. These results indicate that (1) NS cell activity is not radiosensitive and (2) that two signals may be required for maximal NS cell suppression, one being a lymphokine-mediated signal and the other IFN-gamma.     

Neonatal susceptibility to MHV3 infection in mice. I. Transfer of resistance.

Up to 3 weeks of age, mice of the resistant A/J strain are fully susceptible to mouse hepatitis virus type 3 infection (MHV3). Immune deficiency, however, resulting from neonatal thymectomy or long term ALS administration led A/J animals to remain susceptible when tested at adult age. Whole spleen cells transferred from normal adult A/J donor mice protected suckling syngeneic recipients from i.p. infection with MHV3. Such a protective capacity of spleen cells was abolished after treatment with anti-theta serum and complement. Spleen cell separation by means of adherence to plastic also showed that neither the nonadherent nor the adherent populations injected separately were able to confer resistance to young mice challenged with the virus. Protection was not achieved with peritoneal cells originating from adult syngeneic animals. Transfer of resistance to MHV3 was obtained, however, when peritoneal cells were associated with adherent spleen cells. This study indicated that two types of mature cells, at least, were required for transferring MHV3 resistance into newborn mice of the A/J strain: T lymphocytes and an adherent spleen cell population.     

On the differential lipolytic capabilities of rat spleen and cardiac muscle. An in vitro incubation in conjunction with chromatographic and densitometric analysis

The phospholipid profiles of newborn, young adult and aged rat heart and spleen and their in vitro response to endogenous phospholipases at pH 7.4 and 38 degrees C for 60 min were analysed by thin layer chromatography (TLC) technology and densitometry measurement. The noticeable high level of cardiolipin (CL) and its preferential deacylation, as detected by the formation of monolysocardiolipin (MLCL) and concurrent reduction of CL level were the most prevalent lipolytic events of rat cardiac muscle (newborn, young adult and aged) but the least prevalent in rat spleen. The level of ethanolamine plasmalogen (PE) was high in both the rat spleen and cardiac muscle (newborn, young adult and aged). Following in vitro incubation, the reduction in the level of PE and the high level of lyso alkenyl PE produced were most conspicuous in rat spleen (newborn, young adult and aged) and noticeably less in rat cardiac muscle. These data clearly illustrate the differential response of the endogenous substrates (phospholipids) to the endogenous phospholipases of these two tissues, and probably are related to their physiological activities in vivo.     

Determinants of non-toxicity in the gastric pathogen Helicobacter pylori

The Helicobacter pylori vacuolating cytotoxin gene, vacA, is naturally polymorphic, the two most diverse regions being the signal region (which can be type s1 or s2) and the mid region (m1 or m2). Previous work has shown which features of vacA make peptic ulcer and gastric cancer-associated type s1/m1 and s1/m2 strains toxic. vacA s2/m2 strains are associated with lower peptic ulcer and gastric cancer risk and are non-toxic. We now define the features of vacA that determine the non-toxicity of these strains. To do this, we deleted parts of vacA and constructed isogenic hybrid strains in which regions of vacA were exchanged between toxigenic and non-toxigenic strains. We showed that a naturally occurring 12-amino acid hydrophilic N-terminal extension found on s2 VacA blocks vacuolating activity as its removal (to make the strain s1-like) confers activity. The mid region of s2/m2 vacA does not cause the non-vacuolating phenotype, but if VacA is unblocked, it confers cell line specificity of vacuolation as in natural s1/m2 strains. Chromosomal replacement of vacA in a non-toxigenic strain with vacA from a toxigenic strain confers full vacuolating activity proving that this activity is entirely controlled by elements within vacA. This work defines why H. pylori strains with different vacA allelic structures have differing toxicity and provides a rational basis for vacA typing schemes.