Studies of the immunological capacity of germ-free mouse radiation chimeras. IV. Cell-mediated immunity

The cell-mediated immune (CMI) response of germ-free mouse radiation chimeras was compared with that of conventional mice. Spleen or thymus cells from chimeric or normal mice were injected intravenously into lethally irradiated, allogeneic hosts. Spleens of the irradiated hosts were assayed for effector cells using the ⁵¹Cr release assay. Spleen cells from syngeneic and allogeneic chimeras and normal mice were equally active in giving rise to effector cells. However, thymus cells from allogeneic chimeras were completely inactive within 9 months post-bone marrow transplant while thymus cells from syngeneic chimeras and normal mice still remained functional. Although allogeneic chimeras contain cells potentially reactive toward host antigens, cells cytotoxic to host antigens were not detectable. In addition, these studies indicate the helper cell and effector cell, both associated with T-derived lymphocytes, represent two different populations.     

Immune responses in vitro. VII. Loss of susceptibility of functional theta-bearing cells to cytotoxic action of anti-theta serum and complement in vitro

θ-Bearing lymphocytes become progressively less susceptible to cytolytic effects of specific anti-θ serum and complement with incubation in tissue culture. Thymus-derived cell function, in terms of “helper cell” capacity for antibody responses and DNA synthetic responses to phytomitogens, however, remains intact. The data indicate that the loss of susceptibility to cytoloytic effects of anti-θ serum and complement is due to a decrease in the amount of θ antigen on these cells. This phenomenon hampers attempts to determine the length of time that collaborative or “helper” influences of thymusderived cells are required for development of optimal antibody responses in vitro.     

Suppressor T cells induced by soluble immune complexes can adoptively transfer inhibition of cytophilic antibody receptors on macrophages.

Immune complexes (soluble antigens of L1210 and antibody to L1210) when given to allogeneic C3H mice generated suppressor cells that inhibited receptors for cytophilic antibody on macrophages. Thymocytes or nylon-nonadherent splenic T cells (4 × 10⁷) from immune-complex-treated mice transferred this suppressive activity when injected into normal syngeneic mice. Maximal suppression of macrophages occurred 4 to 6 days after transfer. In contrast, even 5 × 10⁷ nylon-adherent, non-T spleen cells from immune-complex-treated (“suppressed”) mice failed to induce macrophage suppression in the syngeneic recipients. When T-cell-depleted “B” mice were used as recipients, neither thymocytes nor splenic T cells from suppressed mice were able to transfer suppressive activity. However, the admixture of 2 × 10⁷ normal syngeneic thymocytes with 4 × 10⁷ thymocytes from suppressed mice restored the latter's ability to elicit suppression of macrophages in T-cell-deprived recipients. Peritoneal monocytes from recipients of suppressor thymocytes (to L1210) could not attach cytophilic antibody to L1210 but could attach cytophilic antibody to EL-4 and sheep erythrocytes. Thus, suppressor T cells induced by immune complexes can transfer immunologically specific macrophage suppression (inhibition of cytophilic antibody receptors) to syngeneic recipients. The suppressor cells required the cooperation of normal T cells, suggesting either recruitment of suppressor cells from, or a helper effect by, the normal T cells, in order to produce their effect.     

Thymectomized, irradiated, and bone marrow-reconstituted chimeras have normal cytolytic T lymphocyte precursors but a defect in lymphokine production

A model system has been developed to study extrathymic T cell differentiation; mice have been thymectomized, lethally irradiated, and reconstituted with bone marrow cells depleted of Thy-1+ cells. After 8 wk, the spleen cells of these athymic, bone marrow-reconstituted chimeras contain Thy-1+ precytolytic T lymphocytes (CTL) that are able to respond to antigen only if supernatant from Con A-activated T cells is added to culture. The phenotype of these pre-CTL is similar to that of thymocytes, suggesting that they may be immature T cells. Initial evaluation of the CTL repertoire of these athymic mice demonstrated that the CTL generated to trinitrophenyl-modified syngeneic cells are H-2-restricted, and that the CTL generated to alloantigens have many of the cross-reactivities observed in normal mice but not in nude mice. In this report, we demonstrate a helper T cell defect in these thymectomized chimeras. These chimeras lack an Ly-1+ helper cell required for thymocytes to differentiate to CTL. Further studies revealed that when spleen cells from these thymectomized chimeras were stimulated with Con A, they produced normal levels of interleukin 2. However, these splenocytes were defective in the production of another factor needed for CTL differentiation.     

Modulation of the helper activity of educated T cells to the synthetic polypeptide poly(Tyr,Glu)-poly(dlAla)-poly(Lys) by adherent cell-bound antigen

The effects of culturing in vivo- or in vitro-activated helper cells on antigen-pulsed splenic adherent cells were studied. In vivo T cells educated to the synthetic polypeptide (T,G)-A-L were obtained by the transfer of thymocytes into lethally irradiated mice. When the activation process was suboptimal, resulting in a low helper function of the cell preparation, incubation of the educated cells on (T,G)-A-L-pulsed splenic adherent cells for 24 hr potentiated their activity, and efficient helper cells were obtained. This process was found to be antigen specific, it did not involve de novo education of naive cells or selection of specific T lymphocytes, but rather completion of the education procedure, which had already started in vivo. It seems that a physical contact between the educated T cells and the antigen-presenting cells is essential for inducing the enhanced helper effect. It is also apparent that during this 24-hr culture on antigen-pulsed macrophages T cells did not proliferate, but rather differentiated into immunocompetent helper cells. On the contrary, when the initial education step was efficient the subsequent culture of the activated T cells on antigen-pulsed splenic adherent cells resulted in a marked decay in the helper function of the cells, while control monolayers were inert. Thus, macrophage-bound antigen differentially modulates the helper function of educated T cells, a procedure which is probably dependent on the degree of maturation or differentiation of the T lymphocyte.     

Mechanisms of antibody formation: I. Early in vivo proliferation of mouse spleen T cells as an initial step in antibody formation

Spleen cultures prepared from mice injected 24 hr earlier with 2 × 10⁶?2 × 10⁸ sRBC and challenged in vitro with sRBC produced 10 times more anti-sRBC IgM PFC than cultures prepared from uninjected mice. The effect was specific for the particular species of foreign RBC injected in vivo. In vitro responses to TNP were also increased in spleen cultures prepared from animals injected 24 or 12 hr earlier with carrier RBC alone, directly implicating carrier-specific T cells in this process. Similar enhancements of PFC formation occurred in cultures prepared from mice which had been injected with sRBC 24 and 48 hr earlier, but which were exposed to lethal irradiation at 1 hr after injection of antigen, if their spleens were shielded extracorporeally during irradiation. This finding indicated that in vivo recruitment of antigen-reactive extrasplenic X-ray-sensitive cells from the circulating lymphocyte pool by the spleen could not account for the observed enhancement.Proliferation in the spleen of antigen-reactive T cells, commencing 12–20 hr after the administration of antigen, was demonstrated by the tritiated thymidine pulse technique. An 8-hr hot-pulse given to spleen cell cultures from normal animals at 20 hr after in vitro challenge with antigen did not affect the rate of generation of IgM-producing cells; however, administration of a similar pulse to cultures which were initiated at 12 or at 20 hr after the in vivo injection of sRBC eliminated the enhanced generation of PFC and delayed the in vitro response to sRBC by 24 hr.Spleen cell cultures were prepared from mice which had been injected in vivo with sRBC at 12, 20, and 70 hr earlier, and 8- to 10-hr hot pulses were given immediately after initiation of the cultures. The cultures were then challenged with sRBC-TNP; antibody responses to TNP were greatly reduced in hot-pulsed cultures prepared from mice injected in vivo with carrier RBC at 12 or 20 hr prior to initiation of the cultures. In contrast, antibody responses to TNP observed in hot-pulsed cultures prepared from mice which had been injected with carrier RBC at 70 hr prior to initiation of the cultures were generally similar to those of nonpulsed 70 hr control cultures. This result suggests that the onset of T helper cell proliferation begins within 12–20 hr after injection of antigen, but subsides in vivo within 70 hr. By that time, the antigen-reactive T cells have already differentiated to perform their helper function.In spite of the triggering of T-cell proliferation during the first 24 hr after injection of antigen, spleen cell cultures prepared from mice which had been injected 24 hr earlier in vivo with 2 × 10⁸ sRBC produced only minimal numbers of anti-sRBC PFC if no antigen was added to the cultures. The presence of unprocessed antigen thus appears to be a requirement for B-cell proliferation in vitro, even after T-cell division has been triggered. This finding is consistent with earlier suggestions that the function of “helper” T cells may not be limited to passive transport of antigenic determinants to B cells. Evidence is also presented to support the contention that the antigen-reactive T cell involved in this process may have to undergo cell division in order to develop “helper” capacity.     

Helper cell function of human fetal thymocytes

The role of human fetal thymocytes in the regulation of IgG and IgM production was examined. In pokeweed mitogen (PWM)-driven cocultures between thymocytes and normal adult peripheral blood mononuclear cells (PBMs) significantly enhanced secretion of both IgM (350% expected; P < 0.02) and IgG (450% expected; P < 0.001) was observed. In contrast, adult PBMs or adult T cells neither suppressed nor enhanced IgM or IgG production in coculture with allogeneic adult PBMs. Enhanced immunoglobulin secretion was not found when fetal thymocytes were cocultured with the T-cell-depleted fraction of adult PBMs. These results suggest that human fetal thymocytes (as early as 12 weeks gestational age) can provide helper cell function for both IgM and IgG secretion in PWM-driven cell cultures; however, a more mature T-cell effector is required for expression of this helper function.     

Fate of H2-activated T lymphocytes in syngeneic hosts. III. Differentiation into long-lived recirculating memory cells.

Memory to H2 determinants was studied with an adoptive transfer system using a population of H2-activated blast T cells (T.TDL) obtained from thoracic duct lymph of irradiated F₁ hybrid mice injected with parental strain T cells. CBA T.TDL activated either to DBA/2 or C57BL determinants were transferred to syngeneic “B” mice. Thoracic duct lymphocytes (TDL) were obtained from the recipients 4–6 weeks later and tested for their capacity to produce (a) a graft-versus-host (GVH) reaction, (b) a mixed lymphocyte reaction (MLR) (measured by an in vivo technique) and (c) allograft rejection (suppression of the growth of allogeneic tumour cells in vivo). Control experiments involved testing the function of TDL obtained from “B” mice preinjected with TDL or no cells.TDL from “B” mice injected with TDL (passaged TDL) gave strong MLR and GVH reactions to both DBA/2 and C57BL determinants. Passaged T.TDL activated to C57BL antigens gave intermediate MLR and GVH reactions to the specific (C57BL) determinants but only very low responses to third-party (DBA/2) determinants; reciprocal results were obtained with passaged T.TDL activated to DBA/2 determinants. TDL from “B” mice given no cells failed to respond to either set of determinants.Since the responses by the passaged T.TDL did not exceed those by passaged TDL there was no evidence that adoptive transfer of T.TDL had conferred to the recipients a state of memory to either MLR or GVH determinants. Adoptive transfer did, however, lead to qualitative changes in the properties of T.TDL since, before transfer, they were unable to evoke GVH reactions or produce an MLR of normal kinetics.Passaged T.TDL were far superior to passaged TDL at suppressing the growth of allogeneic tumour cells. The protection was specific since protection against DBA/2 tumour cells was, cell for cell, 5–10 fold more effective with passaged T.TDL activated to DBA/2 determinants than with cells activated to C57BL determinants. No protection was observed with cells treated with anti-θ serum. The protective cells appeared to be precursors of effector cells rather than effector cells per se since they failed to lyse the tumour cells in vitro. These data suggest therefore that the descendants of T.TDL which survived after transfer to “B” mice were highly enriched in long-lived recirculating T lymphocytes reactive to determinants expressed by specific tumour allografts.     

Accessory cells in the in vitro generation of type C virus-specific T killer lymphocytes. II. Demonstration of a T helper cell in the spleen of in vivo primed mice

The existence of a helper T cell cooperating with cytolytic T lymphocytes (CTL) in cell-mediated anti-tumor responses specific for the virus-induced FMR antigens can be demonstrated by using unprimed thymocytes as CTL precursors and in vivo primed irradiated spleen cells as helper. The helper T cells express Thy-1.2 and Lyt-1.2 antigens at their surface, but not Lyt-2.2. The helper function required the presence of macrophages to be detected, is antigen specific, and appears unusually radiosensitive compared with previously described helper T cell function.     

Subpopulations of splenic T and B lymphocytes producing and regulating leukocyte adherence inhibition factor

Picryl chloride induces contact hypersensitivity in mice, accompanied by spleen cell sensitization that is demonstrable in vitro by specific antigen-induced formation of leukocyte adherence inhibition factor (LAIF). This cellular activity was detected only up to 7 days after sensitization; thereafter the spleen cells appeared to be unreactive with the antigen. The cells were still normally reactive with the mitogen concanavalin A. Antigen reactivity of such “late” cells was restored by passage through a glass-bead column (provided resulting nonadherent cells were reconstituted with normal macrophages), and the restored reactivity was again suppressed by the eluted glass-bead-adherent cells. Suppression was antigen specific. Separation of T and B lymphocytes by affinity chromatography, after glass-bead treatment of sensitized spleen cells, showed that two subpopulations of B cells—those responsible for producing LAIF as well as those suppressing LAIF production by T cells—were glassbead adherent. This was extended by showing directly with anti-Thy-1.2 serum that B cells producing LAIF and suppressor T cells were glass adherent. Thus two suppressive cell populations, and the B cell producing LAIF, were glass adherent while the T-cell LAIF producer was not. Tests for adoptive transfer of cutaneous hypersensitivity in vivo demonstrated the relevance of many of the above observations to conditions in the whole animal. “Late” spleen cells from sensitized mice could not transfer hypersensitivity but this property was restored by glass-bead passage. The eluted adherent cells suppressed transfer. Both adoptive transfer and its suppression were antigen specific.     

Natural killer cell activity in mouse aggregation chimeras

The activity of natural killer (NK) cells in spleen against syngeneic and allogeneic tumor cells was studied by the use of tetraparental mouse chimeras. Chimeras were produced by aggregation of early embryos of histoincompatible mouse strains of “high” and “low” NK cell activity. NK activities of spleen cells were assayed in vitro by the ⁵¹Cr-release method. Coat color distribution and isozymal analysis (glucose-phosphate isomerase) of several lymphoid organs (thymus, lymph nodes, and bone marrow) revealed a predominant share of the “high”-NK-reactive genotype in the chimeras. However, the cellular NK activity against two target cell lines differing in their susceptibility to lysis was significantly lower in chimeras than in the “high”-reactive strain. Addition of “low”-NK spleen cells or of NH₄Cl-inactivated “high”-NK spleen cells to “high”-NK spleen cells inhibited their cytolytic activity. Possible mechanisms of the suppression of the cytolytic capacity of NK cells in chimeras are discussed.     

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.     

Enhancement of the mixed lymphocyte response in the mouse by addition of thymocytes

Synthesis of DNA by mixtures of mouse lymph node and thymic cells was studied in vitro using mitomycin-treated allogeneic spleen cells as stimulator cells. The tests were performed to see whether there occurs a similar cell synergy during this reaction as has been reported during the in vivo graft-vs-host response.It was observed that mixtures of thymocytes and lymph node cells give higher incorporations of isotope-labelled thymidine than can be explained by a pure additive effect of the two cell populations tested separately. This enhancement of the reactivity was more pronounced using combinations of lymph node cells and medullary thymocytes obtained from cortisone-treated donors. Enhancement was also noted between lymph node cells and spleen cells. Blocking of the capacity of lymph node cells to synthesize DNA by treatment with mitomycin abolished this enhanced activity when mixed with thymic cells. On the contrary, mitomycin treatment of thymocytes did not abolish their capacity to increase the reactivity when mixed with normal lymph node cells. Thymocytes, which were unresponsive to the mitomycin-treated cells for genetic reasons, were also found to increase DNA synthesis when combined with lymph node cells. The mechanism by which thymocytes increase DNA synthesis of lymph node cells is not clear, but the results show that they have to be present during the reaction, since culture medium “conditioned” by thymocytes did not exhibit any enhanced capacity to promote a mixed lymphocyte reaction of lymph node cells.The results are thus in agreement with the findings obtained by others showing that mixtures of lymph node cells and thymic cells yield higher immunological reactivities in vivo against foreign transplantation, antigens than can be explained by a pure additive effect of the reactivities by the two cell populations tested separately. However, in contrast to these findings, the thymic cells do not have to be able to synthesize DNA or to react against the foreign cells in vitro to yield an enhanced response when mixed with lymph node cells.     

Immune dysfunction associated with graft-vs-host reaction in mice transplanted across minor histocompatibility barriers. II. Reversible defect in T-dependent antibody responses

B cell and Th cell functions were assessed in mice undergoing a graft-vs-host reaction (GvHR) in response to minor histocompatibility Ag by using the plaque-forming cell (PFC) response to the T-independent Ag TNP-Brucella abortus and the T-dependent Ag TNP-SRBC. Bone marrow plus spleen cells from B10.D2 mice were transplanted into lethally irradiated B10.D2 (syngeneic recipient) or H-2d-compatible BALB/c (allogeneic recipient) to produce a chronic form of GvHR. BALB/c recipients of an allogeneic transplant demonstrated a marked and proportional lymphoid depletion of the spleen with normal percentages of B cells, T cells, and CD4+ and CD8+ T cell subsets. Mice with GvHR made normal numbers of PFC/10(5) spleen cells in response to the T-independent Ag, but a significantly depressed number of PFC/10(5) spleen cells to the T-dependent Ag compared with normal B10.D2 mice and with irradiated B10.D2 recipients of syngeneic B10.D2 marrow plus spleen cells. Mice undergoing the minor Ag GvHR made significantly larger numbers of PFC/10(5) spleen cells after secondary immunization with TNP-SRBC compared with controls. In vitro assays demonstrated that B cells from mice with GvHR responded to T help from normal B10.D2 mice and that T cells from mice with GvHR provided help to normal B cells after in vivo immunization. These data demonstrate that radiation chimeras with GvHR in response to minor histocompatibility Ag have relatively normal B cell function and an apparent defect in T helper cell function that is reversible by immunization with appropriate Ag.     

Nonspecific suppressor elements in murine allogeneic radiation chimeras.

Spleen cells from long-term mouse allogeneic radiation chimeras were tested for their ability to modulate the graft-versus-host (GVH) or plaque-forming cell (PFC) response of normal lymphocytes transplanted in lethally X-irradiated recipients. In vivo GVH proliferation of normal lymphocytes (syngeneic to donor cells of the chimera) against antigens of host-type in which the chimeric state had been established was reduced by chimera cells. Inhibition varied, some chimeras suppressing GVH more than others and a few not suppressing at all. The suppressive effect was abrogated if the chimera cells were treated with anti-θ; treatment with anti-IgM did not eliminate this activity. When mixtures of normal donor lymphocytes and chimera cells were given to irradiated recipients genetically different from host or donor, reduction of donor cell GVH also occurred. Further, chimera cells reduced the GVH activity of normal host cells in irradiated recipients differing from the host at one H-2 locus and from the donor at minor histocompatibility loci. The modulating effect of spleen cells from chimeras on the PFC response by normal lymphocytes also varied. Six chimeras induced a 25 to 90% suppression, two enhanced the response, and one showed no effect. Where suppression occurred, treatment of chimera cells with anti-θ most often, but not always, restored PFC production. Our results show that the suppressive action of splenic lymphoid cells by chimeras is highly nonspecific and variable in expression. We suggest that tolerance in chimeras may be mediated by nonspecific suppressor elements leading to unresponsiveness to a variety of antigens including SRBC.     

Helper cell factors restore antibody responses of allogeneic bone marrow chimeras: evidence for ineffective cellular interactions

We investigated the nature of deficient antibody responses to SRBC in stable, fully allogeneic bone marrow chimeras. No evidence for a suppressor cell-mediated mechanism was found. Chimera spleens possessed adequate numbers of antigen-reactive B cells to produce a normal antibody response. Using separated chimera cell populations and soluble helper factors, we assessed the functional capabilities of chimera B cells, T cells, and macrophages. Our data suggest that the failure of allogeneic chimeras to produce antibody is not the result of impaired B cell, T cell, or macrophage function, but rather that it is due in ineffective cellular interactions that normally result in the generation of helper factors. In vitro stimulation of chimera macrophages with LPS, and of chimera spleen cells with Con A, resulted in the release of soluble helper factors that were capable of fully restoring chimera B cell responses.     

The in vitro effect of a thymic epithelial culture supernatant on mixed lymphocyte reactivity and intracellular cAMP levels of thymocytes and on antibody production to SRBC by Nu/Nu spleen cells.

Addition of supernatants from rat thymic epithelial cultures (TES) to rat thymocytes stimulated with T-cell-mitogens or allogeneic cells leads to an increase in ¹⁴C-TdR incorporation. Furthermore, in the presence of TES, spleen cells from athymic nu/nu mice exhibit an enhanced in vitro antibody production to SRBC, whereas TES has no such effect on spleen cells from T-cell-deprived mice. If TES is added together with thymocytes to T-cell-deprived spleen cell cultures, the number of plaque-forming cells to SRBC is enhanced, suggesting that TES induces a helper cell function in thymocytes which, if added alone, have no effect. TES also increases intracellular levels of cAMP in thymocytes in vitro and appears to act on a membrane site distinct from the β-adrenergic receptor. TES fails to affect mitogen responses, MLR and cAMP levels of lymphocytes from other lymphoid organs. The biological activity of TES as compared to that of thymic extracts is discussed.     

Suppression of natural killer (NK) cell activity of spleen cells by thymocytes

The in vitro influence of thymus cells on natural killer cell activity of spleen cells against prelabeled target cells (YAC-I and RL♂I) has been studied in syngeneic as well as in allogeneic murine models. In mixing experiments to demonstrate suppression, total thymocytes have been found to have no effect on NK activity of syngeneic or allogeneic spleen cells. Among several thymocyte fractions separated by velocity sedimentation, a relatively faster sedimenting fraction showed remarkable suppression of NK activity by spleen cells against two target cells. The suppressive effect of this particular fraction on NK activity was demonstrated to be proportional to the cell dose. The suppressive function was resistant to irradiation at 1000 or 2000 rad administered in vitro and was not restricted by the major histocompatibility complex. Moreover, the thymocyte fraction which induced suppression was not sensitive to NK-mediated cytolysi? by syngeneic spleen cells. The suppression of NK cytolysis in vitro by certain subpopulations of thymocytes as observed in the present studies may be consistent with a role for the thymus in regulating NK activity in vivo.     

Studies of the immunological capacity of germ-free mouse radiation chimeras: I. Chimerism and humoral immune response

The genetic origin of both the functional lymphoid cell and progenitor cell populations of germ-free mouse radiation chimeras was assessed by indirect immunofluorescence (IIF), anti-H-2 cytotoxicity, and survival of lethally x-irradiated secondary recipients of chimera cell populations. These studies demonstrated that germ free C3H/He mice given 1000 R and 10⁷ DBA/2 bone marrow cells express H-2 antigens on their lymphoid and bone marrow cell populations characteristic of the DBA/2 donor. These cells persist for at least 14 months postirradiation and bone marrow transplantation. However, these allogeneic mouse radiation chimeras have a reduced humoral immune response to sheep erythrocytes (SRBC). This decreased humoral immune capacity as assessed by kinetic studies of the spleen plaque-forming cell (PFC) response is present throughout the life span of the chimera. The γ₁ PFC response shows extreme depression. The reduced humoral immune responsiveness to the thymusdependent SRBC antigen is considered to be due to the absence or malfunctioning of a thymocyte population.     

Comparable transforming growth factor beta-mediated immune suppression in ex vivo-expanded natural killer cells from cord blood and peripheral blood: implications for adoptive immunotherapy

T cell-based therapies like genetically modified immune cells expressing chimeric antigen receptors have shown robust anti-cancer activity in vivo, especially in patients with blood cancers. However, extending this approach to an “off-the-shelf” setting can be challenging, as allogeneic T cells carry a significant risk of graft-versus-host disease (GVHD). By contrast, allogeneic natural killer (NK) cells recognize malignant cells without the need for prior antigen exposure and have been used safely in multiple cancer settings without the risk of GVHD. However, similar to T cells, NK cell function is negatively impacted by tumor-induced transforming growth factor beta (TGF-β) secretion, which is a ubiquitous and potent immunosuppressive mechanism employed by most malignancies. Allogeneic NK cells for adoptive immunotherapy can be sourced from peripheral blood (PB) or cord blood (CB), and the authors’ group and others have previously shown that ex vivo expansion and gene engineering can overcome CB-derived NK cells’ functional immaturity and poor cytolytic activity, including in the presence of exogenous TGF-β.  However, a direct comparison of the effects of TGF-β-mediated immune suppression on ex vivo-expanded CB- versus PB-derived NK cell therapy products has not previously been performed. Here the authors show that PB- and CB-derived NK cells have distinctive gene signatures that can be overcome by ex vivo expansion. Additionally, exposure to exogenous TGF-β results in an upregulation of inhibitory receptors on NK cells, a novel immunosuppressive mechanism not previously described. Finally, the authors provide functional and genetic evidence that both PB- and CB-derived NK cells are equivalently susceptible to TGF-β-mediated immune suppression. The authors believe these results provide important mechanistic insights to consider when using ex vivo-expanded, TGF-β-resistant PB- or CB-derived NK cells as novel immunotherapy agents for cancer.