Specific suppression of the in vitro parent anti-hybrid reaction. I. Characterization of a suppressor cell induced in hybrids by pretreatment with parent-strain spleen cells

Spleen cells from B6D2F1 hybrid mice pretreated with 5 X 10(7) B6 spleen cells iv 7 days earlier (B6-pretreated B6D2F1) exhibit a reduced capacity to stimulate the in vitro proliferative and anti-D2 CTL responses of B6 spleen cells. This inability of B6-pretreated B6D2F1 spleen cells to stimulate B6 spleen cells efficiently is due neither to the absence of stimulating cells bearing the D2 alloantigens nor to the destruction of B6 responding cells, but to the presence in the B6-pretreated B6D2F1 cell population of a suppressor mechanism, since the addition of B6-pretreated B6D2F1 spleen cells to a culture of normal B6 responding and irradiated B6D2F1-stimulating spleen cells can suppress the B6 anti-B6D2F1 response. This suppression is mediated by a nylon adherent, Thy-1-negative cell of parent-strain origin which is radioresistant at 2000 R. This suppressor cell is not induced by the injection to B6D2F1 hybrids of spleen cells from the other parent strain (D2) or an allogeneic strain (C3H). It does not suppress either the response of the other parent (D2) or an allogeneic strain (C3H) to B6D2F1 antigens, or the response of B6 cells to an allogeneic strain (C3H).     

Specific inhibition of hybrid resistance in F1 hybrid mice pretreated with parent-strain spleen cells. II. Evidence for an Hh-1 antigen-specific tolerization

Lethally irradiated F1 mice reject bone marrow graft from H-2b parents. In a previous paper we showed that pretreatment of F1 hybrid with H-2b parental spleen cells abrogates this hybrid resistance (HR) to parental bone marrow growth by inducing a Thy-1+Lyt-1+2- nylon-adherent suppressor cell. We studied the mechanism of induction of this suppressor cell. Two hypotheses were tested; both were based on the observation that parental spleen cells when injected into a F1 hybrid, recognize the alloantigens of the opposite parent and proliferate; the proliferation of these Hh-1+ cells may result in an overload of the pretreated F1 hybrids with Hh-1 Ag, and in the development of a graft-vs-host reaction that is followed by a non-specific immunodeficiency (GVHID). Thus abrogation of HR could be due to either a tolerization with high doses of Hh-1 Ag or the GVHID. Our results show that abrogation of HR does not correlate with the GVHID because 1) it is induced after pre-treatment with H-2b parental cells only, whereas GVHID is observed after injection with cells from either of the two parents; and 2) it is induced in several conditions where GVHID does not occur; after pre-treatment with 1000-rad-irradiated or T-cell depleted or only class I incompatible spleen cells or with spleen cells from nude parents as well as after pre-treatment with H-2b bone marrow cells. HR is overcome by the injection of H-2Db homozygous or of cross-reactive H-2Ds homozygous cells only. However, although pretreatment with H-2Db homozygous spleen cells is necessary, it is not sufficient for an efficient overcoming of HR. Indeed enhancement of H-2b bone marrow growth after pre-treatment with 1000-rad-irradiated, T-cell depleted or nude parent spleen cells is very short-lasting and never reaches the level observed after pre-treatment with normal spleen cells. We conclude that inhibition of HR in F1 hybrids pretreated with parental spleen cells is not a consequence of a GVHID but of a specific tolerization with Hh-1 Ag; however, the HR is inhibited more consistently when inoculum used for the pretreatment contains fully immunocompetent T cells. The role of the immunocompetent parental T cells in abrogation of HR is discussed.     

Inhibition of mouse bone marrow granulocyte-macrophage colony formation by factors derived from natural killer cells: an in vitro model for hybrid resistance

Investigations were performed to study whether soluble factors produced by NK-cells could mediate "hybrid resistance" in vitro. NK-cells enriched from spleens of B6D2F1 hybrid mice were incubated with parental B6 bone marrow, and the effect of the derived supernatants on the development of granulocyte-macrophage colony forming cells (GM-CFC) was assessed. Cell free supernatants obtained from low density cells (LDC) of B6D2F1 hybrids stimulated with bone marrow cells (BMC) from B6 mice inhibited GM-CFC formation. The inhibition was similar using B6, D2 or B6D2F1 bone marrow cells as the targets for GM-CFC growth. Our findings suggest that NK cells from F1 hybrid mice when stimulated with BMC from B6 mice release inhibitory factors, different from IFN-gamma and that this production may represent a mechanism of natural resistance to parental H-2b bone marrow grafts.     

Murine cytomegalovirus infection can enhance hybrid resistance through modulation of host natural killer activity

Studies were undertaken to assess the effect of murine cytomegalovirus (MCMV) in two different models involving injection of parental cells into F1 hosts. In both of these systems, MCMV-induced enhancement of hybrid resistance was found. In the first model, parent-into-F1 graft-vs-host reaction, MCMV infection of (C57BL/6 x C3H)F1 (B6C3F1) hosts was found to prevent the GVHR normally induced by injection of B6 parental splenocytes into the F1 hosts. The second model involved injection of parental bone marrow into lethally irradiated B6C3F1 and (C57BL/6 x DBA/2)F1 (B6D2F1) hosts. These irradiated hosts are known to exhibit resistance to engraftment by parental C57BL/6 (B6) bone marrow. This resistance was found to be markedly enhanced by injection of the hosts with MCMV 3 days before irradiation and bone marrow injection. In contrast, engraftment into B6C3F1 hosts of syngeneic marrow, or bone marrow from the C3H parent, was not affected by MCMV infection. Engraftment of DBA/2 marrow into B6D2F1 hosts was reduced at lower doses of injected marrow, suggesting enhanced resistance against the minor Hh Ag Hh-DBA. To test whether the MCMV-induced enhancement of resistance was mediated by NK cells, splenic NK activity (YAC-1 killing) and frequency (NK1.1 staining) were assessed. Both parameters were found to be elevated at 3 days after MCMV infection but to return to normal levels by 9 days. B6 bone marrow engraftment was in fact found to be normal when the marrow was administered to F1 mice 9 days after MCMV infection. Furthermore, anti-asialoGM1 administration prevented MCMV-induced enhancement of resistance to marrow engraftment. Thus, the NK enhancement resulting from MCMV infection appears to play a major role in the enhanced HR observed in the marrow engraftment model. This effect may be of importance in clinical bone marrow transplantation, a situation in which patients are susceptible to viral infection.     

Hybrid resistance to parental mast cell precursors in the skin of (WB X C57BL/6)F1-W/Wv mice

When bone marrow cells of (WB X C57BL/6)F1-+/+ (WBB6F1-+/+) and WB-+/+ (WB) mice were directly injected into the skin of genetically mast cell-deficient WBB6F1-W/Wv mice, mast cell clusters appeared at the injection sites. However, the number of WB bone marrow cells necessary for appearance of mast cell clusters was significantly larger than when bone marrow cells of WBB6F1-+/+ mice were used. When WB bone marrow cells were mixed either with WB thymus cells or with silica particles, the proportion of injection sites at which mast cell clusters appeared increased to the level that was observed after the injection of the same number of WBB6F1-+/+ bone marrow cells. When suckling WBB6F1-W/Wv mice of less than or equal to 18 days of age were used as recipients, bone marrow cells of WBB6F1-+/+ and WB mice produced mast cell clusters with a comparable efficiency. Both syngeneic thymus cells and silica particles are known to abrogate the hybrid resistance that is observed in the spleen against parental hematopoietic stem cells. The hybrid resistance in the spleen is not detectable in suckling mice, either. Thus, the poor growth of mast cell precursors in the skin and the poor growth of hematopoietic stem cells in the spleen seem to be regulated by the same mechanism.     

Abrogation of hybrid resistance to bone marrow engraftment by graft-vs-host-induced immune deficiency

Lethally irradiated F1 mice, heterozygous at the hematopoietic histocompatibility locus Hh-1, which is linked with H-2Db, reject bone marrow grafts from H-2b parents. This hybrid resistance (HR) is reduced by prior injection of H-2b parental spleen cells. Because injection of parental spleen cells produces a profound suppression of F1 immune functions, we investigated whether parental-induced abrogation of HR was due to graft-vs-host-induced immune deficiency (GVHID). HR was assessed by quantifying engraftment of H-2b bone marrow in F1 mice with the use of splenic [125I]IUdR uptake; GVHID, by the ability of F1 spleen cells to generate cytotoxic T lymphocytes (CTL) in vitro. We observed a correlation in the time course and spleen cell dose dependence between loss of HR and GVHID. Both GVHID and loss of HR were dependent on injection of parental T cells; nude or T-depleted spleen cells were ineffective. The injection of B10 recombinant congenic spleens into (B10 X B10.A)F1 mice, before grafting with B10 marrow, demonstrated that only those disparities in major histocompatibility antigens that generated GVH would result in loss of HR. Thus, spleens from (B10 X B10.A(2R]F1 mice (Class I disparity only) did not induce GVHID or affect HR, whereas (B10 X B10.A(5R))F1 spleens (Class I and II disparity) abrogated CTL generation and HR completely. GVHID produced by a class II only disparity, as in (B10 X B10.A(5R))F1 spleens injected into (B6bm12 X B10.A(5R))F1 mice, was also sufficient to markedly reduce HR to B10 bone marrow. This evidence that GVHID can modulate hematopoietic graft rejection may be relevant to the mechanisms of natural resistance to marrow grafts in man.     

Specific inhibition of hybrid resistance in F1 hybrid mice pretreated with parent-strain spleen cells. III. Study of the mechanism

The rejection of H-2b parental bone marrow graft by lethally irradiated F1 recipients, that is known as hybrid resistance (HR), is a multistep process. In a first step a 5-fluorouracil (5-FU)-sensitive T cell recognizes the parental bone marrow cells and stimulates a macrophage-like cell to secrete IFN-alpha/beta (recognition phase). IFN-alpha/beta in turn activates a cyclophosphamide-sensitive NK-like cell that is the effector cell for HR (effector phase). In a previous paper we described that HR is specifically abrogated by the pretreatment of the F1 recipient with H-2b parental spleen cells. This abrogation is due to a Thy-1+CD5+CD4+CD8- nylon adherent suppressor cell of F1 origin. The aim of the present work was to study during which of the different phases of HR the activity of the suppressor cell is exerted. Our results showed that abrogation of HR in (C57BL/6 x C3H)F1 (B6C3F1) hybrids pretreated with B6 spleen cells results from: 1) the suppression of the 5-FU-sensitive T cell; 2) the suppression of the cyclophosphamide-sensitive NK-like cell; and 3) the disappearance of a humoral factor that is present in the serum of normal B6C3F1 hybrids and which seems to be involved in the effector phase of HR. The 5-FU-sensitive T cell is the only target of Thy-1+CD5+CD4+CD8- suppressor cell. The mechanisms responsible for the suppression of the NK-like effector cell and the disappearance of the humoral factor are discussed.     

Defective transient endogenous spleen colony formation in S1/S1d mice.

WCB6F1 mice of the genotype S1/S1d did not form transient 5-day endogenous spleen colonies following midlethal irradiation, either spontaneously or in response to postirradiation bleeding. Their hematologically normal (+/+) littermates produced colonies equivalent in number and morphologic type to a normal strain (D2B6F1), as evaluated by both macroscopic and microscopic criteria. Bone marrow cells from S1/S1d mice, when transplanted into lethally irradiated +/+ mice, were able to generate equivalent numbers of transient endogenous spleen colonies (TE-CFUs), as compared to that obtained when syngeneic +/+ marrow cells were injected into lethally irradiated +/+ recipients. A defective growth of an early class of hematopoietic progenitor cells, resulting in the clinical course of the S1/S1d anemia is suggested and confirms previous reports on the microenvironmental nature of this abnormality.     

Induction of tolerance to parental marrow grafts in F1 hybrid mice. Evidence for recognition of self-antigens

Lethally irradiated (C57BL/6xC3H)F1 mice are able to acutely reject parental C57BL/6 but not C3H marrow grafts, a phenomenon called hybrid resistance (HR). In attempts to inactivate this rejection mechanism we found that parental spleen cells activated with LPS are very potent in inducing tolerance to a subsequent C57BL/6 marrow graft. Tolerance is likely due to elimination of effector cells responsible for graft rejection as adoptive transfer of spleen cells from normal into tolerized mice reconstitutes responsiveness. Evidence is presented that the Ag on LPS-activated spleen cells responsible for induction of unresponsiveness are expressed on both C57BL/6 and (C57BL/6xC3H)F1 cells. This suggests that the HR effector cells recognize autoantigens. In support of this, induction of tolerance to C57BL/6 parental marrow grafts leads to a concomitant dramatic increase in endogenous CFU-spleen after a dose of gamma-irradiation. Moreover, elimination of the cells responsible for HR by injection of anti-ASGM1 antibody results in a similar increase of endogenous CFU-spleen after irradiation. It is concluded that HR is a reflection of autoimmunity, able to limit the proliferation of syngeneic marrow stem cells.     

Leucyl-leucine methyl ester treatment of donor cells permits establishment of immunocompetent parent----F1 chimeras that are selectively tolerant of host alloantigens

Treatment of murine lymphocytes with L-leucyl-L-leucine methyl ester (Leu-Leu-OMe) selectively removes natural killer cells, cytotoxic T lymphocyte precursors, and the capacity to cause lethal graft-vs-host disease, whereas bone marrow stem cell function and alloantigen-induced L3T4+ T helper function remains intact. The present studies assess the immunocompetence of allogeneic bone marrow chimeras established by reconstituting irradiated (C57BL/6 X DBA/2)F1 (B6D2F1) mice with Leu-Leu-OMe-treated C57BL/6 (B6) bone marrow and spleen cells. Spleen cells from such chimeras were found to have normal B and T cell mitogenic responses. Furthermore, levels of natural-killer cell function were comparable to those observed in B6----B6 syngeneic radiation chimeras established without Leu-Leu-OMe treatment of donor cells. Spleen cells from B6----B6D2F1 mice were identical with B6----B6 or B6 mice in allostimulatory capacity and thus contained no discernible cells of non-H-2b phenotype. Whereas B6----B6D2F1 spleen cells demonstrated alloproliferative and allocytotoxic responses toward H-2k bearing spleen cells, no H-2d specific proliferative or cytotoxic responses could be elicited. B6----B6D2F1 spleen cells did not suppress the generation of anti-H-2d or anti-H-2k proliferative or cytotoxic responses from control B6 spleen cells. Furthermore, addition of rat concanavalin A supernatants did not reconstitute anti-H-2d responses of B6----B6D2F1 chimeric spleen cells. Thus, Leu-Leu-OMe treatment of B6 donor cells not only prevents lethal graft-vs-host disease, but also permits establishment of long-lived parent----F1 chimeras that are selectively tolerant of host H-2 disparate alloantigens, but fully immunocompetent with respect to natural killer cell function, B and T cell mitogenesis, and anti-third party alloresponsiveness.     

Specific suppression of the in vitro parent anti-hybrid reaction: II. Parameters influencing suppressor cell induction in the F1 hybrid

In the accompanying paper (K. Kosmatopoulos et al. Cell. Immunol.104, 319–334, 1987) we have reported that the spleens of B6D2F1 hybrids pretreated with B6 spleen cells 7 days earlier contain a cell which specifically suppresses the in vitro proliferative and cytotoxic B6 anti-B6D2F1 responses. The results we present here concern the in vivo conditions under which this suppressor cell can be induced. Suppressor cell activity appears early after the injection of B6 spleen cells (day +1), increases on Day 7, and disappears by Day 30; it is always detectable after the injection of 5 × 10⁷ B6 spleen cells and never after the injection of 1.25 × 10⁷ cells, the intermediate dose of 2.5 × 10⁷ cells being followed by variable results. This variability is attributable to the age of B6 donor and B6D2F1 recipient mice, and suppression is never observed when 2.5 × 10⁷ spleen cells from 6-week-old B6 mice are injected into 6-week-old B6D2F1 hybrids. The suppressor cell is induced by the injection of B6 spleen cells of the Thy-1⁺ Ly-1⁻2⁺ phenotype, even if they are irradiated at 1000 R just before their injection. Lymph node cells from B6 mice induce the suppressor cell, whereas thymocytes do not. Irradiation of B6D2F1 hybrids at 600 or 950 R does not prevent the induction of suppressor cell, nor does thymectomy. Moreover, in the thymectomized or 600 R-irradiated B6D2F1 animals suppression can be induced even by the injection of only 1.25 × 10⁷ B6 spleen cells. This phenomenon of specific suppression is not limited to the B6-B6D2F1 genetic combination since it has been observed in all parent-hybrid combinations tested to date.     

The effects of polyinosinic:polycytidylic acid (pI:C) on the graft-vs-host (GVH) reaction. II. Increased NK-mediated rejection on C57BL/6 lymphocytes by (C57BL/6 X A)F1 mice

We previously demonstrated that treatment of (C57BL/6 X A)F1 (F1) recipient mice with polyinosinic:polycytidylic acid (pI:C) before injection with 30 X 10(6) C57BL/6 (B6) lymphocytes prevents both the immunosuppression and pathologic lesions typical of graft-vs-host (GVH) reactions. We now report the further characterization of this phenomenon. Donor spleen and lymph node cells were labeled with fluorescein in vitro and injected into pI:C-treated or untreated mice. Two days later, recipient splenocytes were analyzed for the presence of fluorescein-labeled donor cells by flow microfluorometry. Treatment of F1 mice with pI:C resulted in a sharp reduction in the recovery of labeled B6 but not A strain parental cells. Treatment with pI:C had no effect when syngeneic recipients were used, or when F1 cells were injected into A, B6, or F1 recipients. These results suggest that pI:C treatment induces rejection of B6 but not A or F1 lymphocytes by F1 hybrid mice at least as early as 2 days after donor cell transfer. As F1 cells are not rejected by either parent, rejection does not seem to be directed against classical alloantigens. These observations are compatible with the previously described model of hybrid resistance (HR) against bone marrow grafts. The rapidity of rejection strongly suggested that natural cytotoxic mechanisms were involved, thus, natural killer (NK) cell and macrophage (M phi) cytotoxic activities were tested throughout the time when the parental cell graft was being rejected. Over this period, pI:C treatment increased cytotoxic activity against the NK-sensitive target cell line YAC-1 but had no effect on spontaneous M phi tumoricidal activity against the L5178Y and MDAY-D2 cell lines. The results suggest that NK cells, but not M phi, may be involved in the elimination of B6 parental cells by the pI:C-treated F1 mice. NK cells have been demonstrated to be radioresistant; thus, as a test of our hypothesis, we examined the effects of irradiation on the capacity of pI:C treated F1 mice to reject B6 lymphocytes. The results show that this capacity was not blocked by 750 cGy, a dose of radiation that abrogates most T and B cell functions. Furthermore, rejection of parental cells could be prevented by treatment of recipient F1 mice with antibodies to asialo GM1, a treatment that suppresses NK activity. These data demonstrate that pI:C-mediated protection from GVH-induced changes is due to increased rejection of grafted B6 parental cells by F1 NK cells, a phenomenon very similar, if not identical, to HR to bone marrow grafts.     

Expression of hemopoietic histocompatibility antigens on H-2-loss variants of F1 hybrid lymphoma cells: evidence consistent with trans gene regulation

H-2 heterozygous marrow stem cells, lymphoid progenitor cells, and leukemia/lymphoma cells do not express hemopoietic or hybrid histocompatibility (Hh) antigens, which are important transplantation antigens recognized during the rejection of normal or neoplastic hemopoietic cells. The Hh-1b determinant of the H-2b haplotype maps to the D region of H-2. We have tested the hypothesis that gene(s) at or near H-2D of the H-2d haplotype down-regulate the expression of Hh-1b in the trans configuration. We used Abelson leukemia virus-transformed pre-B lymphoma cells (ACCb) of BALB/c X BALB.B (H-2d X H-2b) origin, as well as variant lines of ACCb, which were selected for resistance to monoclonal anti-H-2 antibodies plus complement. B6D2F1 (H-2b X H-2d), C3B6F1 (H-2k X H-2b), or B6 (H-2b) mice were infused with inocula of 5 X 10(6) B6 bone marrow cells (BMC). Proliferation of donor-derived marrow cells was judged in terms of DNA synthesis by measuring the splenic incorporation of 5-iodo(125I)-2'-deoxyuridine (IUdR) 5 days after cell transfer. B6 BMC grew much better in B6 than in F1 hybrid host mice, an expression of "hybrid resistance". As observed previously, the injection of EL-4 (H-2b, Hh-1b) tumor cells prior to infusion of B6 (H-2b, Hh-1b) BMC enhanced the growth of B6 BMC in F1 hybrid mice. Therefore, this in vivo "cold target cell competition" type of assay can be used to detect the expression of Hh-1b antigens. Unlike EL-4 (H-2b) cells, hybrid resistance was not affected by prior infusion of (H-2b X H-2d) heterozygous ACCb cells. In contrast, three ACCb variant cell lines, H-2d-, Ld-Dd-, and Dd-, enhanced the growth of B6 BMC in F1 hosts. The ACCb H-2b- cell line did not affect hybrid resistance to B6 BMC. The loss of gene expression on the H-2d chromosome at or very near the H-2Dd locus is correlated with the appearance Hh-1b, as determined by the in vivo cold target competition assay. These results support the hypothesis that heterozygous cells possess trans-acting, dominant, down-regulatory genes mapping near H-2D that control the Hh-1 phenotype of lymphoid tumor cells.     

Resistance to murine leukemia in mice rejecting syngeneic somatic hybrid cells.

(A/J X C3H/HeJ) F1 mice reject somatic cell hybrids of ASL-1 cells (A origin) and LM(TK)- cells (C3H origin), but die from leukemia within 10 days after the inoculation of approximately 10(6) viable ASL-1 cells. Mice rejecting hybrid cells survive for prolonged periods after challenge with otherwise lethal numbers of ASL-1 cells. The hybrid cells, rejected by syngeneic F1 recipients, retained their oncogenic potential as determined by the appearance and progressive growth of tumors in immunologically deficient nu/nu mice injected with the cells. Similar results were obtained using hybrids of a radiation-induced cell line (RADA-1), maintained by serial transfer in strain A mice and LM(TK)- cells. Syngeneic mice injected with RADA-1 X LM(TK)- cells failed to form tumors. Mice rejecting RADA-1 X LM(TK)- hybrid cells survived for prolonged periods after challenge with otherwise lethal numbers of RADA-1 cells.     

Experimental models for prevention of graft-versus-host reaction in bone marrow transfusion. I. Selective suppression and augmentation of splenomegaly and cytotoxicity.

Induction and suppression of splenomegaly and cytotoxicity against C57BL/L cells were studied in (AKR X C57BL/6) F1 hybrid adult mice after the transfer of AKR lymphoid and bone marrow cells. 1) Splenomegaly and cytotoxicity were dissociated in the developmental stages of the graft-versus-host reaction. When lymphoid and bone marrow cells of normal AKR mice were injected into F1 recipients, splenomegaly was prominent on days 5 and 7, but cytotoxicity of spleen cells was not detected. Splenomegaly became less prominent but the cytotoxicity became detectable on day 14 after the injection. 2) Cytotoxic activity of spleen cells of F1 recipients was suppressed by the treatment of AKR donors with C57BL/6 lymphoid cells in Freund's complete adjuvant. Splenomegaly, however, was substantially enhanced by such a treatment of the donors. On the other hand, induction of the cytotoxic activity was facilitated by the treatment of donors with C57BL/6 skin grafts. 3) F1 hybrid mice could be protected from the graft-versus-host reaction by the injection of AKR anti-C57BL/6 serum or pretreatment of AKR donors with sonicated cellular antigens of C57BL/6.     

F1 hybrid resistance: Long-term systemic effects sensitive to irradiation and age

In contrast to the usual rapid growth of transplanted syngeneic marrow cells in spleens of lethally irradiated recipients, the growth of parental marrow cells from certain inbred strains of mice is resisted by their F_l hybrids, other strains or both. The full complexity of this well known natural resistance is demonstrated here by using three inbred strains and their three Fl hybrids in all parent-hybrid combinations of donor and recipient. A similar resistance to parental marrow grafts is reported here in W-anemic F₁ hybrid recipients that are cured and repopulated without irradiation. Rather than resistance to short-term growth in spleens, F₁-hybrid resistance to permanent repopulation of the entire hemopoietic system is studied here. This manifestation of hybrid resistance is radiosensitive and declines in recipients over the age of 12 months. Long-term hemopoietic repopulation is measured quantitatively by injecting mixtures of two marrow-cell types with distinguishable hemoglobins into stem-cell-deficient recipients. A very high degree of resistance is detected against WB but not 136 parental marrow when mixed with WBB6F₁ marrow and injected into WBB6F₁ recipients. Most, but not all, of this resistance to permanent, systemic repopulation is abrogated by irradiation of the recipients; it is also abrogated after they reach the age of 15 months. Mouse models of long-term hybrid resistance studied in the entire hemopoietic system may be particularly relevant for marrow transplantation in man, where the objective is long-term systemic repopulation.     

Augmentation of syngeneic tumor-specific immunity by semiallogeneic cell hybrids

Hybrid cell lines were established from fusions between lipopolysaccharide- (LPS) stimulated C57BL/6J spleen cells and MPC-11 tumor cells (45.6TG1.7, abbreviated M45), and were tested for their ability to immunize semiallogeneic mice against a parental tumor challenge. These hybrids were tumorigenic in syngeneic (BALB/c X C57BL/6J) F1 (CB6F1) mice but did not grow in semiallogeneic (BALB/c X A/J) F1 (CAF1) mice. All hybrids express both parental major histocompatibility antigens (H-2b and H-2d) as detected by indirect immunofluorescence and by their ability to function as either stimulators or targets for allogeneic cytotoxic lymphocytes (CTL). M45 tumor-associated antigens (TAA) were expressed on the hybrid surface as shown by their ability to act as either stimulators or targets for syngeneic CTL specific for M45 TAA. Immunization of semiallogeneic CAF1 mice with the hybrids i.p. followed by a challenge with M45 tumor cells resulted in extended survival when compared to untreated mice or animals immunized i.p. with M45 tumor cells. This immunity was specific and was not due to an allogeneic effect; immunization with an unrelated H-2bd tumor, 70Z/3, or H-2bd B6D2F1 spleen cells or with semiallogeneic spleen cells plus M45 did not protect mice from M45 challenge. Interestingly, prophylactic priming with semiallogeneic hybrid tumor cells or parental myeloma cells led to M45-specific CTL and "help" for an in vitro CTL response; however, the degree of CTL priming by hybrid tumors was not augmented when compared to the level of CTL achieved with parental tumor alone. Hence, stimulation of CTL activity per se by hybrid tumor cells cannot explain the protective effect of hybrid tumor immunization. These studies nevertheless confirm that semiallogeneic hybrids, which we show express TAA and alloantigens, can be used to immunize mice against a lethal syngeneic myeloma tumor challenge.     

Mechanism of hybrid resistance. The role of a natural antibody in parental bone marrow cell rejection

Hybrid resistance (HR) to parental bone marrow growth is specifically directed against hemopoietic histocompatibility (Hh-1) Ag that are present in parental bone marrow cells (bmc). The mechanism of HR seems to be a multistep process. According to a model we proposed earlier, a T cell recognizes the Hh-1 Ag and stimulates a macrophage to secrete IFN-alpha/beta (recognition phase). IFN-alpha/beta activates a NK-like cell that specifically kills the parental bmc (effector phase). We have also described in a previous paper that serum from resistant F1 hybrids contains a humoral factor that seems to be involved in the effector phase of HR. In the present work, we study the role and the nature of this humoral factor. Our results show that this humoral factor: 1) is present in all resistant H-2Db heterozygous F1 hybrids we have tested but not in nonresistant H-2Db homozygous mice; 2) seems to recognize the Hh-1b Ag because it is absorbed on bmc from Hh-1b mice but not on bmc from Hh-1d and Hh-1- mice; and 3) is an IgG1 Ig (natural antibody). These results could help us to explain the specificity of HR at the effector phase by supposing that this natural antibody recognize the Hh-1 Ag and enable NK-like cells to kill parental bmc cells in Hh-1 specific manner.     

Experimental Models for Prevention of Graft-versus-Host Reaction in Bone Marrow Transfusion

Induction and suppression of splenomegaly and cytotoxicity against C57BL/6 cells were studied in (AKR × C57BL/6) F1 hybrid adult mice after the transfer of AKR lymphoid and bone marrow cells. 1) Splenomegaly and cytotoxicity were dissociated in the developmental stages of the graft-versus-host reaction. When lymphoid and bone marrow cells of normal AKR mice were injected into F1 recipients, splenomegaly was prominent on days 5 and 7, but cytotoxicity of spleen cells was not detected. Splenomegaly became less prominent but the cytotoxicity became detectable on day 14 after the injection. 2) Cytotoxic activity of spleen cells of F1 recipients was suppressed by the treatment of AKR donors with C57BL/6 lymphoid cells in Freund's complete adjuvant. Splenomegaly, however, was substantially enhanced by such a treatment of the donors. On the other hand, induction of the cytotoxic activity was facilitated by the treatment of donors with C57BL/6 skin grafts. 3) F1 hybrid mice could be protected from the graft-versus-host reaction by the injection of AKR anti-C57BL/6 serum or pretreatment of AKR donors with sonicated cellular antigens of C57BL/6.     

Age-related osteopenia: evidence for an intrinsic defect of bone resorbing cells and a possible treatment

B6D2F1 and B6AF1 mice of various ages were given sublethal or lethal doses of X radiation and injected with marrow and/or spleen cells from young, mature, or old syngeneic donors. Four to five months later they were killed and ash weights were determined on femurs, sacrum, and ilium. It was found that large numbers of marrow cells (i.e., greater than 25 X 10(6] and/or spleen cells (greater than 50 X 10(6] from old mice retarded the growth of bone in young hosts and induce loss of bone mass in mature recipients, spleen cells from young donors consistently prevented the loss of bone mass normally seen in aging mice, and the thymus and T cells did not appear to play a significant role in bone resorption and remodeling. These observations suggested that in aging mice loss of bone mass is caused by an intrinsic defect in a hematopoietic cell population, perhaps the macrophage/osteoclast or their common precursor, which results directly or indirectly in increased bone resorption. On this basis, promethazine HCl, an inhibitor of macrophage metabolism and phagocytosis, was added to the drinking water (1.0 to 4.0 mg/dl) of aging mice. Four to five months later it was found that bone mass was significantly greater in the groups given promethazine than in the age and weight matched controls.