In vitro reactivity of splenic lymphocytes from normal and UV-irradiated mice against syngeneic UV-induced tumors.

Skin tumors induced in mice by chronic ultraviolet (UV) irradiation are highly antigenic and are frequently immunologically rejected upon transplantation to normal syngeneic recipients. In this study we characterized this immune response with an in vitro microcytotoxicity test. Cytotoxic activity was present in the spleen cells of mice given a single injection of syngeneic UV-induced fibrosarcoma cells. After removal of adherent spleen cells, the remaining splenic lymphocytes were specifically cytotoxic for the immunizing tumor and showed no cross-reactivity with other syngeneic UV-induced or methylcholanthrene-induced tumors of similar histologic type. The level of cell-mediated reactivity against UV-induced tumors was quite high compared to that obtained with syngeneic tumors induced by methylcholanthrene, and the cytotoxicity was attributable to a population of theta antigen-bearing lymphocytes. With this in vitro test, we compared the response of normal mice, which reject a syngeneic tumor challenge, with that of UV-irradiated mice, in which the syngeneic UV-induced tumors grow progressively. After tumor cell inoculation, lymphocytes form the unirradiated (regressor) mice showed a high degree of cytotoxicity that reached a maximum level 8 days after injection. In contrast, no reactivity could be detected in the spleens of tumor-challenged UV-irradiated (progressor) mice.     

Specific inhibition of cytotoxic memory cells produced against UV-induced tumors in UV-irradiated mice.

Cytotoxic responses of UV-irradiated mice against syngeneic UV-induced tumors were measured by using a 51Cr-release assay to determine if UV treatment induced a specific reduction of cytotoxic activity. The in vivo and in vitro primary responses against syngeneic tumors and allogeneic cells were unaffected, as was the "memory" response (in vivo stimulation, in vitro restimulation) against alloantigens. In contrast, the memory response of UV-treated mice against syngeneic, UV-induced tumors was consistently and significantly depressed. The cytotoxicity generated by tumor cell stimulation in vivo or in vitro was tumor-specific and T cell-dependent. Since the primary response against syngeneic UV-induced tumors produces apparently normal amounts of tumor-specific cytotoxic activity, UV-treated mice may not reject transplanted syngeneic tumors because of too few T effector memory cells. These results imply that, at least in this system, tumor rejection depends mostly on the secondary responses against tumor antigens and that at least one carcinogen can, indirectly, specifically regulate immune responses.     

Regulation of the immune response against UV-induced skin cancers: specificity of helper cells and their susceptibility to UV-induced suppressor cells

The purpose of this study was to determine the role of T helper (Th) cells in the immune response to UV-induced tumors. Repeated exposure of mice to UV radiation results in the production of suppressor T lymphocytes that facilitate tumor growth by inhibiting host immunity. To investigate whether the suppressor T cells inhibit the response to UV tumors by blocking the generation of Th, we employed an indirect method for measuring helper cell activity. We found that Th were produced in normal mice after immunization with UV-induced tumors. These Th appeared to be specific for the immunizing tumors, in contrast to the UV-induced suppressor cells, which recognize UV-induced tumors as a group. The suppressor T cells responsible for inhibiting tumor rejection have no effect on tumor-specific helper cell activity in vitro. However, UV-induced suppressor T cells transferred into unirradiated mice seem to block the generation of helper cell activity after immunization with UV-produced tumors. These results suggest the UV-induced suppressor cells may prevent tumor rejection by blocking the generation of Th.     

Characterization of a cloned ultraviolet radiation (UV)-induced suppressor T cell line that is capable of inhibiting anti-UV tumor-immune responses

Ultraviolet radiation (UV) is a potent carcinogen for the induction of skin tumors. In this regard, UV represents a unique carcinogenic agent, in that depending on the dosage and conditions of administration it can function as either a complete carcinogen, a carcinogenic promoting agent, or an immunologic modulator of anti-tumor rejection responses. The immunologic modulatory activity of UV has been demonstrated in numerous studies. These studies have shown that subcarcinogenic doses of UV induce a population of suppressor T lymphocytes (Ts cells) that allow for the emergence and progression of UV-induced tumors. Although the phenotypic and functional properties of these cells have been established, it was unclear as to whether the UV-induced Ts cell population consisted of multiple Ts cell clones able to recognize a range of unique tumor antigens or a limited number of Ts cell clones with functional specificity directed toward a common tumor-associated antigen (TAA). To address this question, an interleukin 2-dependent, UV-induced cloned Ts cell line was derived, by limiting dilution without exogenous antigen stimulation, from the splenic T cell population of a C3H mouse that had been exposed to a subcarcinogenic dose of UV. This Ts cell line, designated UV2.10, was selected for its ability to suppress the in vitro differentiation of cytotoxic T cells from the draining lymph nodes of UV-induced tumor-immune mice. When transferred into non-UV-irradiated syngeneic mice, which normally reject a UV-induced tumor implant, the UV2.10 cells rendered their hosts susceptible to the growth of a battery of UV-induced tumors. Although capable of suppressing in vitro and in vivo UV-induced tumor-immune responses, UV2.10 cells did not inhibit the elicitation of contact hypersensitivity responses, the rejection of allogeneic skin grafts, responses, the rejection of allogeneic skin grafts, or the rejection of allogeneic UV-induced tumors. These data suggest that the cloned UV2.10 Ts cell line possesses functional antigenic specificity that may be limited to the regulation of immune responses that are directed toward the TAA expressed by syngeneic UV-induced tumors. Employing monoclonal antibodies and FACS analysis, the cell surface phenotype of the UV2.10 cell line was determined to be: Thy-1.2+, Lyt-1-, Lyt-2+/- (dim), L3T4a-, I-A/E-, and I-J+. This cell surface phenotype is indicative of a suppressor T cell. These data lend further support to the hypothesis that the UV-induced Ts cell population is clonal in nature and functions through its ability to recognize a common TAA(s) that appears to be expressed by virtually all UV-induced tumors.     

IL-10 controls ultraviolet-induced carcinogenesis in mice

UV radiation-induced immunosuppression contributes significantly to the development of UV-induced skin cancer by inhibiting protective immune responses. IL-10 has been shown to be a key mediator of UV-induced immunosuppression. To investigate the role of IL-10 during photocarcinogenesis, groups of IL-10(+/+), IL-10(+/-), and IL-10(-/-) mice were chronically irradiated with UV. IL-10(+/+) and IL-10(+/-) mice developed skin cancer to similar extents, whereas IL-10(-/-) mice were protected against the induction of skin malignancies by UV. Because UV is able to induce regulatory T cells, which play a role in the suppression of protective immunity, UV-induced regulatory T cell function was analyzed. Splenic regulatory T cells from UV-irradiated IL-10(-/-) mice were unable to confer immunosuppression upon transfer into naive recipients. UV-induced CD4+CD25+ T cells from IL-10(-/-) mice showed impaired suppressor function when cocultured with conventional CD4+CD25- T cells. CD4+CD25- T cells from IL-10(-/-) mice produced increased amounts of IFN-gamma and enhanced numbers of CD4+TIM-3+ T cells were detectable within UV-induced tumors in IL-10(-/-) mice, suggesting strong Th1-driven immunity. Mice treated with CD8+ T cells from UV-irradiated IL-10(-/-) mice rejected a UV tumor challenge significantly faster, and augmented numbers of granzyme A+ cells were detected within injected UV tumors in IL-10(-/-) animals, suggesting marked antitumoral CTL responses. Together, these findings indicate that IL-10 is critically involved in antitumoral immunity during photocarcinogenesis. Moreover, these results point out the crucial role of Th1 responses and UV-induced regulatory T cell function in the protection against UV-induced tumor development.     

Generation of tumor-specific transplantation antigens by UV radiation can occur independently of neoplastic transformation

The purpose of this study was to determine whether the UV-associated antigens present on tumors induced in mice by chronic UV irradiation could be induced by in vitro irradiation of cells that were already tumorigenic, or whether their occurrence was associated with the primary neoplastic transformation event. Cells of a nonantigenic, spontaneous fibrosarcoma cell line were exposed to UV radiation in vitro, were cloned, and were tested for antigenic properties. A large number of the clones obtained after UV irradiation of the fibrosarcoma cells were highly antigenic (20 of 39), whereas clones derived from unirradiated cultures were not (0 of 10). The antigenic variants did not induce cross-protection among themselves, but induced only variant-specific immunity in vivo. Several antigenic variants were tested for susceptibility to the action of UV-induced suppressor cells, which seem to recognize a common determinant shared among UV-induced tumors. The variants tested were indeed subject to the activity of the UV-induced suppressor lymphocytes. These results demonstrate that the unique antigenic properties exhibited by UV-induced murine skin cancers are also exhibited by cells exposed to UV radiation in vitro. In addition, they imply that the UV-associated antigens arise as a consequence of exposing cells to UV radiation and that they can occur independently of an initial neoplastic transformation event.     

Immunologic significance of nonspecific suppressor cells in spleens of tumor-bearing mice.

Spleen cells from mice bearing a progressively growing syngeneic tumor failed to respond to stimulation with mitogens in vitro. This lack of reactivity was due to the presence of nylon wool-adherent cells in the population that could inhibit the mitogen response of normal lymphocytes. Paradoxically, at times when strong suppressor cell activity could be detected in tumor-bearing mice, the animals responded normally to in vivo immunization with sheep erythrocytes and allogeneic tumors, and to in vitro sensitization with allogeneic tumor cells. Regression of a highly antigenic syngeneic tumor also was unaffected by the presence of these suppressor cells. Thus, the occurrence of nonspecific suppressor cells in the spleens of tumor-bearing mice did not influence the overall immunologic competence of these animals.     

Anti-tumor effects of an antiserum raised in syngeneic mice to a tumor-specific T suppressor factor

Summary DBA/2 mice inoculated with either cells from the syngeneic P815 tumor or tumor cell membrane extracts develop T suppressor cells which suppress the in vitro generation of cytotoxic T lymphocytes with specificity for the tumor. A soluble suppressor factor with similar properties can be isolated from suppressor cell-enriched populations. It can be highly purified by appropriate immunoadsorption. Antisera to this suppressor factor raised in either DBA/2 or C57BL/6 mice can specifically absorb out suppressor factor and eliminate suppressor cells in the presence of complement. The in vivo effects of these antisera were tested for their ability to modulate the growth of P815 tumors in DBA/2 mice. It was found that the antiserum raised in syngeneic (DBA/2) but not allogeneic (C57BL/6) mice was able to significantly slow the rate of tumor growth and to prolong survival in treated mice. The antiserum was effective in this way only if it was administered early in the course of tumor growth. It was shown that this effect was not attributable to the presence in the serum of antibodies directed to antigens present on P815 cells, and it therefore appears to be due to interference with the function of T suppressor cells arising early in the immune response to the tumor cells.     

An important role of CD80/CD86-CTLA-4 signaling during photocarcinogenesis in mice

Although previous studies have shown that altered B7 costimulation plays a critical role in UV irradiation-induced regulation of immunity, the individual roles of the B7 receptors (CD28 and CTLA-4) or the B7 family members (CD80 and CD86) have not been explored. Thus, we investigated CTLA-4 signaling during photocarcinogenesis of chronically UV-B-exposed mice using an antagonistic anti-CTLA-4 Ab. Anti-CTLA-4-treated mice developed significantly fewer UV-induced tumors. Moreover, anti-CTLA-4 treatment induced long-lasting protective immunity because progressively growing UV tumors inoculated into anti-CTLA-4- and UV-treated mice that had not developed tumors were rejected. Next, we used mice deficient for CD80, CD86, or both in photocarcinogenesis studies to assess the relative contributions of these CTLA-4 ligands. Double-deficient mice showed significantly reduced UV-induced skin tumor development, whereas CD86(-/-) mice produced skin cancer earlier compared with CD80(-/-) and control mice. The growth of UV-induced tumors appears to be controlled by UV-induced suppressor T cells, because CD80(-/-)/CD86(-/-) mice had strongly reduced numbers of UV-induced CD4(+)CD25(+) suppressor T cells. In vitro, CTLA-4 blockade inhibited the suppressor activity of UV-induced CD4(+)CD25(+) T cells, suggesting that reduced photocarcinogenesis might be due to decreased numbers or function of suppressor T cells. Together, these data indicate that blocking CD80/86-CTLA-4 signaling induced immune protection against the development of UV-induced skin tumors. Furthermore, CD86-mediated costimulation appears to play a more critical role in the protection against photocarcinogenesis than CD80.     

Activity of tumor-associated lymphoid cells at short intervals after administration of irradiated syngeneic and allogeneic tumor cells.

After a single intraperitoneal injection of irradiated tumor cells, host cells capable of responding against syngeneic tumors were detected in peritoneal exudates of mice. Although irradiation of the injected tumor prevented its overgrowth, it did not significantly alter the antigenicity of the tumor. Immunologic activities of tumor-associated host cells in the peritoneal cavity were continuously monitored, starting 48 hr after tumor administration. In vitro cell-mediated lysis of syngeneic tumors appeared as early as 3 days after irradiated tumor administration. In addition, peritoneal exudate cells from inoculated mice were capable of adoptively transferring immunity. Purification of these peritoneal exudate cells on nylon wool columns yielded a nonadherent Ig-negative lymphocyte fraction whose cytolysis was tumor-specific and T cell-associated. The macrophage-free lymphocyte fraction exhibited a higher in vitro activity against tumors than unpurified peritoneal exudates. This tumor-host system allowed the study of cells which directly interact with the tumor cells in vivo, starting shortly after tumor administration. The results reported in this paper show that tumor-associated lymphoid cells capable of mounting anti-tumor response in vivo and in vitro can be demonstrated as early as 3 days after tumor inoculation.     

Reversal of CD8+ T cell ignorance and induction of anti-tumor immunity by peptide-pulsed APC

In the present report, we have studied the potential of naive and activated effector CD8(+) T cells to function as anti-tumor T cells to a solid tumor using OVA-specific T cells from TCR-transgenic OT-I mice. Adoptive transfer of naive OT-I T cells into tumor-bearing syngeneic mice did not inhibit tumor cell growth. The adoptively transferred OT-I T cells did not proliferate in lymphoid tissue of tumor-bearing mice and were not anergized by the tumor. In contrast, adoptive transfer of preactivated OT-I CTL inhibited tumor growth in a dose-dependent manner, indicating that E.G7 was susceptible to immune effector cells. Importantly, naive OT-I T cells proliferated and elicited an anti-tumor response if they were adoptively transferred into normal or CD4-deficient mice that were then vaccinated with GM-CSF-induced bone marrow-derived OVA-pulsed APC. Collectively, these data indicate that even though naive tumor-specific T cells are present at a relatively high fraction they remain ignorant of the tumor and demonstrate that a CD8-mediated anti-tumor response can be induced by Ag-pulsed APC without CD4 T cell help.     

Cell cooperation in abolition of tolerance of xenogeneic tumor.

Thymectomized, lethally irradiated mice reconstituted with syngeneic bone marrow cells are tolerant to xenogeneic Yoshida ascites sarcoma (YAS). The tolerance was abolished by an injection of syngeneic normal spleen, thymus, or lymph node cells given simultaneously with YAS. Allogeneic and semiallogeneic spleen cells were ineffective. The YAS-rejecting mice produced specific anti-tumor antibodies. The serum of these mice transferred to tolerant T-cell-deficient mice protected the latter from inoculated YAS cells. These serum-protected mice were not able to resist the reinoculum of the tumor cells as the mice restored with lymphoid cells did. The latter mice rejected the YAS at the time when donor cells were practically absent in their lymphoid tissue. The low effective ratio of injected syngeneic lymphoid to tumor cells, efficiency of injected thymus cells, and other data led to the conclusion that transferred lymphoid cells did not act directly on tumor cells but through cooperation with host lymphoid cells. The cooperation of donor T- and host B-lymphocytes enabled the activation of the latter, and YAS cells were rejected.     

Studies of allogeneic tumor transplants: induced rejection of advanced tumors by immune alteration of recipients

In the present experiments, a methylcholanthrene-induced sarcoma (S-702) of B10.D2 origin was found to grow rapidly in B6AF1 mice leading to the death of all recipients in 5 to 9 wk. Nevertheless, immunity to MHC antigens presented by the tumor was readily demonstrable in tumor-bearing mice by their responses to donor strain skin grafts until late in the course of tumor growth, when a nonspecific form of immune suppression developed. In addition, B6AF1 mice preimmunized by exposure to B10.D2 donor strain antigens did not permit tumor growth. Treatment of tumor-bearing B6AF1 mice with CY at 18 days, when the tumors measured over 12-mm in diameter, followed by the i.p. injection of B10.D2 lymphoid cells (at a dosage of from 1.2 to 2.5 X 10(8) cells) resulted in the complete regression of 100% of these large tumors. CY treatment combined with localized immune stimuli in the form of donor strain skin grafts or secondary tumor implants was incapable of producing a sufficiently heightened immune response to cause tumor rejection. A dose of CY temporarily retarded tumor growth in most mice, and in a minority of animals so treated (less than 25%) tumors regressed completely. In syngeneic (B10.D2) animals, CY also temporarily slowed tumor growth, but total regression was never observed. An effective B10.D2 cell inoculum could consist not only of living lymphoid cells but of irradiated (1000 rad) cells as well. Tumor cell suspensions (after irradiation, 10,000 rad) were also effective. These observations suggest local immune factors at the host-tumor interface may have been of importance in the survival of these allogeneic tumor transplants and that CY influenced this state, perhaps through an influence on suppressor cells, allowing subsequent administration of donor strain cellular antigens to induce an effective tumor rejection response.     

Identification and cytotoxic reactivity of inflammatory cells recovered from progressing or regressing syngeneic UV-induced murine tumors.

Most tumors induced in C3H mice by ultraviolet (UV) light are immunologically rejected by normal syngeneic recipients, but will grow progressively in immunosuppressed mice and in mice treated with UV light. In this study we compared the composition and cytotoxic activity of the inflammatory cell infiltrate from tumors transplanted into syngeneic UV-irradiated or unirradiated mice. Tumor fragments were implanted in either normal (regressor) or UV-treated (progressor) mice, and removed on various days after implantation and mechanically dissociated. The cells were examined by immunofluorescence for theta and immunoglobulin markers, stained for morphologic examination, and tested for cytotoxicity against the tumor. No significant differences were noted in numbers of macrophages, granulocytes, or B cells recovered from progressing or regressing tumors on day 6, the time of greatest activity. However, the numbers of T cells recovered from tumor fragments implanted in normal mice was approximately 3-fold that recovered from tumor fragments implanted in UV-treated mice. Lymphocytes recovered from regressing tumor fragments were specifically cytotoxic for that tumor in a microcytotoxicity test; those from progressing tumor fragments were not cytotoxic.     

The immunological role of the thymus in the pathogenesis of virus-induced lymphomas. Suppression of cytolytic T-cell function

Thymectomy of young adult mice has been found to prevent virus-induced lymphomas which develop as the animals age. Thymectomy protects mice by removing a source of suppressor T cells which inhibit the generation of cytolytic T cells against autochthonous tumors. Furthermore, suppression is specific since T cells are regulated in their capacity to respond to syngeneic but not allogeneic tumor cells. To determine if suppression could be adoptively transferred, lethally irradiated, bone-marrow-reconstituted mice were inoculated with T cells from either normal or thymectomized mice. Only T cells from thymectomized animals transferred enhanced T-cell reactivity to syngeneic tumor cells. More importantly, T cells from thymectomized mice injected with virus protected recipients challenged with lethal doses of syngeneic tumor cells. We conclude that thymectomy protects mice from developing virus-induced T-cell lymphomas by removing a source of suppressor T cells which regulates the activity of specific cytolytic T cells directed against autochthonous tumor cells.     

Evidence for the generation of suppressor cells by ultraviolet radiation

The majority of murine skin tumor induced with ultraviolet (uv) light are unique in that they are of sufficient antigenicity to be consistently rejected when transplanted into normal syngeneic animals. However, the exposure of normal syngeneic mice to subcarcinogenic levels of uv prior to tumor transfer results in the progressive growth of transplanted uv-tumors. We report that normal mice can also be rendered tumor susceptible by the adoptive transfer of lymphoid cells from either tumor bearing or short term uv exposed donors. Further, the adoptive transfer of tumor susceptibility can be abolished by the pretreatment of cell suspensions from uv exposed donors with anti-theta and complement. These results suggest that uv irradiation may generate the development of T lymphocytes with suppressor activity.     

An innate host response to the neoplastic cell: syngeneic rat tumor cells can elicit a rapid de novo lymphoid procoagulant response

To analyze unique molecular differences between normal and neoplastic cells, we have examined host responses to tumor cells. The present study provides the first evidence for an innate rapid recognitive response of the lymphoid system to some syngeneic tumors. The lymphoid procoagulant (PCA) response, a T cell-instructed monocyte response that activates proteases of the coagulation cascade culminating in thrombin formation, is considered a component of classic delayed-type hypersensitivity responses. We have demonstrated that three syngeneic rat mammary carcinomas elicit this cellular response in vitro in lymphoid cells of the unimmunized rat. The response was rapid, reaching maximum within 6 hr. Analysis was compounded by the constitutive PCA activity of some tumors; however, the PCA product produced in the response to tumor challenge in vitro was newly biosynthesized and was of lymphoid cell origin, differing from the PCA of tumor cells. The lymphoid PCA response was prothrombinase-like and did not require vitamin K for biosynthesis, nor were other gamma-carboxylation-dependent extrinsic pathway proteases other than prothrombin required for thrombin generation. Both in vivo and in vitro derived mammary carcinoma cells elicited the response, whereas a fibrosarcoma and nontransformed syngeneic cells did not. Tumor shed substances, which were devoid of PCA and sedimentable only in part at 100,000 X G, induced this cellular response. The same stimuli shed from tumor cells did not directly elicit a PCA response from elicited peritoneal macrophages; however, in the presence of T lymphocytes a PCA response of these macrophages was produced. This study provides novel information to indicate that a T-enriched lymphocyte-dependent monocyte-macrophage response to some tumors, before effective in vivo immunization, may participate in initial local protease generation and fibrin deposition, both thought to play a significant role in the local pathobiology of tumors.     

The effect of radiation therapy combined with natural killer cells against spontaneous murine fibrosarcoma

The effect of radiation therapy combined with lymphoid cells against spontaneous murine fibrosarcoma (FSa-II) was investigated bothin vivo andin vitro. In thein vivo experiment, syngeneic C3H mice were divided into 3 groups. Animals in the first group were injected with 1 x 10⁵ tumor cells into the right hind leg. Animals in the second and third groups were injected with 1 x 10⁵ tumor cells mixed with 1 x 10⁷ normal lymphoid cells (NLC) or effector lymphoid cells (ELC), respectively. ELC were obtained from spleen and lymph nodes of FSa-II-bearing mice and incubatedin vitro for 40 hr to eliminate suppressor T cell function. NLC were obtained from normal mice and incubated in the same way. Irradiation was given using¹³⁷Cs unit 3 days after cell inoculation. 12 out of 14 mice (85.7%) inoculated with tumor cells mixed with NLC did not show any tumor growth at 60 Gy local irradiation. 12 out of 21 mice (57.1 %) inoculated with tumor cells alone and 6 out of 10 (60%) with tumor cells mixed with ELC rejected tumors at the same radiation dose. This synergistic effect with NLC was not observed when NLC was inoculated after irradiation, indicating that lymphoid cells should be in contact with tumor cells before irradiation. In the⁵¹Cr release assay, lymphoid cells obtained from whole body irradiated (WBI) mice showed 17.8% lysis without irradiation and 28.8% lysis at 5 Gy irradiation. Untreated NLC showed almost no cytotoxic effect at the same radiation dose. This synergistic effect disappeared when WBI lymphoid cells were treated with anti asialo GM1 and complement. These results suggested that NK cells might be important in this synergistic effect with irradiation. To obtain a sufficient level of synergistic effect by in vitro combined treatment of mixed tumor cell - NLC culture and irradiation - incubation for more than 12 hrs and 8 hrs appeared to be necessary before and after irradiation, respectively.     

Mechanisms of depressed reactivity to dinitrochlorobenzene and ultraviolet-induced tumors during ultraviolet carcinogenesis in BALB/c mice

Chronic treatment of BALB/c mice with ultraviolet (uv) radiation produces two distinct immunologic deficiencies. These deficiencies are apparent long before visible skin tumors are induced by the uv irradiation. One is reflected in a transient inability to develop delayed hypersensitivity to dinitrochlorobenzene and appears to be due to a defect in antigen processing. The other is expressed by the failure of mice to reject syngeneic uv-induced tumors, which are highly antigenic. This lack of tumor rejection can be passively transferred with lymphoid cells and seems to be due to the presence of specific suppressor lymphocytes.     

Natural suppressor (NS) cells found in the spleen of neonatal mice and adult mice given total lymphoid irradiation (TLI) express the null surface phenotype

We studied the surface markers of suppressor cells of the mixed leukocyte reaction (MLR) that are transiently present in the spleens of neonatal mice after birth and of adult mice after total lymphoid irradiation (TLI). Approximately 80% of the mononuclear cells in the spleen, within the first few days after birth or after TLI, express neither the Thy-1 antigen nor surface immunoglobulin (Ig). After 30 days, less than 20% of mononuclear cells bear this null phenotype. With the use of the panning technique, we showed that the suppressors of the MLR are confined to the null cell population. The null suppressor cells are not macrophages because they did not carry macrophage markers identified by the monoclonal antibodies anti-MAC-1 and F4/80. In addition, the suppressor cells did not stain for nonspecific esterase and did not adhere firmly to plastic or glass. Spleen cells from TLI-treated mice maintained their suppressive capacity after culture in vitro for 6 to 8 wk. The cultured suppressor cells did not develop mature T cell, B cell, or macrophage markers during this time interval. Thus, the suppressor cells did not appear to be precursors of the latter cells. There was no clear relationship between the suppressor activity of the spleens and natural killer (NK) activity; the kinetics of these activities in newborn spleen appear to be inversely related. The suppressor cells, however, are similar to NK cells in that both are found in the absence of antigenic challenge, lack antigen specificity, and bear the null surface phenotype. Thus, we have termed the former cells natural suppressor (NS) cells.