NK-mediated elimination of mutant lymphocytes that have lost expression of MHC class I molecules.

Mutant cells generated in vivo can be eliminated when mutated gene products are presented as altered MHC/peptide complexes and recognized by T cells. Diminished expression of MHC/peptide complexes enables mutant cells to escape recognition by T cells. In the present study, we tested the hypothesis that mutant lymphocytes lacking expression of MHC class I molecules are eliminated by autologous NK cells. In H-2b/k F1 mice, the frequency of H-2Kb-negative T cells was higher than that of H-2Kk-negative T cells. The frequency of H-2K-deficient T cells increased transiently after total body irradiation. During recovery from irradiation, H-2Kk-negative T cells disappeared more rapidly than H-2Kb-negative T cells. The disappearance of H-2K-deficient T cells was inhibited by administration of Ab against asialo-GM1. H-2Kk-negative T cells showed higher sensitivity to autologous NK cells in vitro than H-2Kb/k heterozygous or H-2Kb-negative T cells. Adding syngeneic NK cells to in vitro cultures prevented emergence of mutant cells lacking H-2Kk expression but had little effect on the emergence of mutant cells lacking H-2Kb expression. Results in the H-2b/k F1 strain correspond with the sensitivity of parental H-2-homozygous cells in models of marrow graft rejection. In H-2b/d F1 mice, there was no significant difference between the frequencies of H-2Kb-negative and H-2Kd-negative T cells, although the frequencies of mutant cells were different after radiation exposure among the strains examined. H-2b/d F1 mice also showed rapid disappearance of the mutant T cells after irradiation, and administration of Ab against asialo-GM1 inhibited the disappearance of H-2K-deficient T cells in H-2b/d F1 mice. Our results provide direct evidence that autologous NK cells eliminate mutant cell populations that have lost expression of self-MHC class I molecules.

Simultaneous immunoselection in vitro for H-Y or H-2D antigen-loss variants of a mouse-derived B cell line.

Cytotoxic T lymphocytes (CTL) specifically reactive with the male transplantation antigen (H-Y) were used to immunoselect in vitro for antigen loss among cells from an Abelson murine leukemia virus (AbMuLV) transformed lymphoblastoid cell line. Numerous variant cell clones were recovered that had lost expression of either H-Y or the restricting major histocompatibility class I molecule, H-2D. In all experiments, low-level gamma-irradiation applied prior to immunoselection increased the frequency of antigen loss, but when different time intervals between mutagenesis and immunoselection were used, the proportion of H-Y to H-2D antigen loss was affected, suggesting that the antigens selected against remain on the surface of the cell for differing amounts of time following allele loss.

Increased surface expression of class I MHC molecules on immunogenic cells derived from the xenogenization of P815 mastocytoma cells with 8-methoxypsoralen and long-wavelength ultraviolet radiation.

In a previous study we demonstrated that the treatment of the highly tumorigenic cell line, P815, with 8-methoxypsoralen and long-wavelength ultraviolet radiation resulted in the production of several immunogenic clones (tum-). Mice inoculated with the tum- cells survived much longer than mice inoculated with the original tumorigenic cells (tum+). It was suggested that the increased survival of mice treated with the tum- clones arose as a result of an increased antigenicity derived from the phototreatment. In this report we show that the tum- cells have a greater density of class I MHC molecules on their surface (50-157% compared to P815). Class I MHC density on the cell surface is required to elicit targeted cytotoxic responses. These results can be considered in terms of human class I MHC assays which show that many human tumor cells have a reduced expression of class I MHC. Because other DNA damaging agents have also been shown to enhance class I expression, it is suggested that in addition to the cytotoxic effects of these agents, other pleiotropic effects must be considered. Photochemotherapy may phenotypically alter cells so that the enhanced expression of class I MHC molecules on the surface of phototreated cells may be associated with the clinical responses observed in cutaneous T cell lymphoma patients.

Mutant frequency at the H-2K class 1 and HPRT genes in T lymphocytes from the X-ray-exposed mouse.

The frequency of H-2Kk and HPRT-deficient T cells was measured in the H-2Kb, kDd,k genotype mouse 8-10 weeks after X-ray exposure at doses up to 6 Gy to compare the mutant frequency (MF) of an autosomal gene with that of an X-chromosomal gene. H-2K mutants were enriched by magnetic cell separation (MACS) using the H-2Kk-specific monoclonal antibody H100.5/28 and were isolated by limiting dilution cloning. Finally, the mutant phenotype was verified by flow cytometric analysis in a representative number of clones. The frequency of HPRT-deficient T cells rises from 2.5 x 10(-6) at 0 Gy to a maximum of 1.13 x 10(-4) at 4 Gy, and decreases to 2.9 x 10(-5) at 6 Gy. The H-2K- MF in the non-irradiated mouse was 8.4 x 10(-7). It increases with dose to a maximum of 8.1 x 10(-6) at 4 Gy and declines to 3.3 x 10(-6) at 6 Gy. The H-2K- MF measured depends on the monoclonal antibody used for the isolation of mutants. In a pilot study with another H-2Kk-specific monoclonal antibody (11.4.1), the spontaneous MF was four times higher than in experiments with the H100.5/28 monoclonal antibody. The expression of other class 1 antigens was investigated in H-2K- clones. The H-2Dd antigen had also disappeared in six of 41 clones from irradiated animals. This gene is situated at a distance of 1500 kb from the K-locus. The H-2Kb antigen was present in every investigated clone. In the discussion a model is presented that explains the shape of the dose-response curve of MF by selection against mutants in vivo systems under homeostasis. The results of the present investigation indicate that observed X-ray mutagenicity depends on many factors and that several genes have to be explored before reliable risk estimates are possible.

Radiation-enhanced expression of major histocompatibility complex class I antigen H-2Db in B16 melanoma cells.

Exposure of eukaryotic cells to ionizing radiation induces several cellular responses including DNA repair, arrest of DNA synthesis, and increased synthesis of specific cellular proteins. We derived from the murine melanoma cell line B16-F10 a clonal isolate (M1) that was exposed to a total dose of 5000 cGy in 25 fractions, according to a protocol that reflects the standard for current radiotherapeutic regimens. We measured, by flow cytometry of fluorescence-stained cells, the surface expression of the two major histocompatibility complex class I antigens H-2Db and H-2Kb in irradiated M1 cells and untreated M1 controls. We found that after 2000 cGy, expression of H-2Db antigen was enhanced in irradiated cells versus controls. Radiation-induced expression of H-2Db antigen appeared to be selective, since no up-regulation of the H-2Kb antigen was detectable, and persisted for at least 5 weeks following the last irradiation. Enhanced H-2Db antigen expression correlated with increased steady-state levels of H-2Db mRNA in irradiated cells. These results are consistent with the notion that enhanced expression of major histocompatibility complex class I antigens is part of a long-lasting stress response elicited in cells by radiation.

[The effect of iron carrier proteins on the transplantation of H-2 locus-incompatible bone marrow in irradiated mice]. / Vliianie zhelezonesushchikh belkov na transplantatsiiu nesovmestimogo po H-2 lokusu kostnogo mozga obluchennym mysham.

Rabbit bone marrow supernatants were fractionated and purified by Ultrogel and Superose chromatography. A unique fraction promoted engraftment of allogenic bone marrow and enduring hemopoietic chimerism across the histocompatibility (H-2) barrier in lethally irradiated mice. This fraction analysed by reducing SDS-PAGE electrophoresis and transblotted on PVDF membrane or purified by reverse-phase HPLC and SDS-PAGE electrophoresis yielded a main pre-albumin band that was examined for primary structure by Edman degradation. It appeared to be rabbit transferrin. Iron saturated human transferrin, lactotransferrin and egg transferrin (conalbumin) were then tested in irradiated C57B1/6 mice transplanted with bone marrow from histoincompatible BALB/CJ donors. Most mice treated with iron-loaded transferrins survived and developed enduring allogeneic chimerism with no discernible signs of graft-versus-host disease at 10 months posttransplant. Observation of these animals is still carried on. Iron carrier proteins seem to provide a novel unexpected means for achieving a successful engraftment of allogeneic bone marrow in immunologically hostile murine H-2 combinations and may open a new approach in the clinical area.

Proportion of antigenic variants induced by in vitro UV irradiation differs in clones derived from a single tumor.

The purpose of this study was to examine the capacity of different clones derived from the same tumor to generate highly antigenic cells after in vitro exposure to UV radiation. Cells from the metastatic murine melanoma K1735 and clones of K1735 differing in metastatic potential were exposed to UV radiation in vitro, cloned, and tested for antigenic properties in vivo. Approximately half of the clones isolated after UV irradiation of parental K1735 melanoma cells were highly antigenic (five of nine). Similar treatment of cells of a nonmetastatic clone of K1735 generated clones that were all antigenic (nine of nine). In contrast, only one of nine clones derived from UV-irradiated cells of a highly metastatic clone of K1735 were antigenic. Clones derived from unirradiated cultures were not antigenic variants. The increased antigenicity of cells derived from UV-irradiated cultures did not correlate with an increase in expression of cell surface class I major histocompatibility complex antigens. These results demonstrate that the frequency of antigenic variant production after UV irradiation is an intrinsic property of the particular cell line used, and that even cloned cell lines derived from a single tumor differ in their ability to generate antigenic variants after UV irradiation. In addition, they indicate that the increased antigenicity is not necessarily due to a UV-induced increase in expression of cell surface class I histocompatibility antigens.

[Changes in the antigenic phenotype of mouse thymocytes after exposure to chemical inducers of differentiation and ionizing radiation]. / Izmenenie antigennogo fenotipa timotsitov myshei pri deistvii khimicheskikh induktorov differentsirovki i ioniziruiushchei radiatsii.

Irradiation of a mouse thymocyte fraction enriched by T-lymphocyte precursors changes the antigenic phenotype of cells toward the increase of their highly differentiated forms. Similar changes in membrane marker antigens are produced by chemical inductors of differentiation and thymotropin. The changes in the cell phenotype induced by the above agents are associated with both membrane and intragenome rearrangements. The results of the experiments on preventing the expression of some antigens by puromycin and the data on the level of spontaneous genome lesions in thymocyte fractions have prompted an assumption that destabilization of the genome upon irradiation increases DNA injury above some critical level which may serve a stimulus for "sorting out" the most radiosensitive thymocyte fraction.

The role of donor lymphoid cells in the transfer of allograft tolerance.

Tolerance to murine skin allografts across a MHC disparity was induced by conditioning primary hosts with sublethal fractionated total-body irradiation (FTBI) and transfusion of allogeneic bone marrow (BM). Tolerance could be adoptively transferred to secondary hosts conditioned by FTBI with infusion of spleen cells from hosts bearing intact skin allografts greater than 60 days. Tolerance could not be transferred by tolerant host spleen (THS) preparations from which cells of the donor genotype had been deleted by cytotoxic alloantisera. Deletion of host genotype cells, however, did not diminish the capability of THS to transfer tolerance. All of the tolerizing activity of THS appeared to reside within cells of the donor genotype. Small numbers of normal donor spleen cells could induce tolerance in FTBI hosts but only at the expense of very high mortality, in contrast to the low mortality observed with tolerizing injections of allogeneic donor cells from THS or injections of normal semiallogeneic F1 hybrid spleen cells. If an active immune response is responsible for tolerance induction/transfer in this model, allogeneic donor lymphoid cells derived from BM, in contrast to donor spleen cells, must be capable of mounting this response without concomitant severe GVHD. In future experiments, cells of donor genotype can be isolated from THS and purified in sufficient numbers to compare their tolerizing efficiency vs. that of normal donor cells, detect possible suppression of normal host cell alloreactivity in vitro and identify the donor cell phenotypes involved.

Experimental manipulations and marrow-derived factors which affect the outcome of bone marrow transplantation across the H-2 barrier in lethally irradiated mice.

A system is illustrated here for transplantation of bone marrow (BMT) across the H-2 barrier in conventionally raised mice. Timing of BM inoculation after supralethal irradiation, alteration of cellular composition of BM cell inoculum, sex of donor and recipient, inoculation or removal of BM-derived supernatants, use of BM-derived factors were all variables which profoundly affected survival, hemopoietic engraftment and induction of permanent, irreversible chimerism in different strains of mice (H-2d, H-2b, H-2k) transplanted with allogeneic BM. Inoculation of BM shortly after irradiation and addition or removal of plastic-adherent cells to the BM adversely affected survival and chimerism. Also inoculation of BM in its original supernatant containing all extracellular, endogenous BM factors resulted in increased mortality. BM-derived regulating factors (MRF) exerted variable effects in different H-2 combinations. However, heat-stable components of MRF greatly affected survival and chimerism. BM-derived supernatants and MRF from rabbit or different murine H-2 types thus seem to contain powerful inhibitors and promoters of BM engraftment. Promoters stimulate allogeneic BM engraftment, are heat-resistant and non-species specific. The different character and concentration of those factors between different H-2 types is also illustrated by their in vitro effects on BM cells. These results demonstrate that different experimental manipulations and factors which do not strictly depend on genetic diversity between donor and recipient profoundly affect allogeneic BMT. Adoption of manipulations combined with use of non-T cell depleted BM and the still largely unidentified BM-derived factors result in increment of survival and lasting chimerism without any manifestation of early or late graft versus-host disease (GVHD).

Comparison of altered expression of histocompatibility antigens with altered immune function in murine spleen cells treated with ultraviolet radiation and/or TPA.

Previous studies in our laboratory demonstrated that several treatments that inhibited the ability of cells to stimulate the mixed lymphocyte reaction (MLR) also blocked the shedding of histocompatibility antigens and Ia antigens from murine spleen cells. In the present studies, one of these treatments, ultraviolet radiation (UV), was shown to cause an initial loss in the density of H-2K, IA, and IE antigens prior to the block in shedding observed after culture of these cells. Further analysis revealed that the UV-induced loss of antigens could be prevented by the presence of colchicine during irradiation. Biosynthetic analyses revealed the IA antigen synthesis was also inhibited in the UV-irradiated cells. Examination of the effects of a second agent, 12-0-tetradecanoylphorbol-13-acetate (TPA) on the turnover of histocompatibility antigens revealed that the biosynthesis and shedding of these antigens were accelerated by this agent. However, addition of TPA to UV-irradiated cells did not result in a reversal of the UV-induced block in biosynthesis of IA antigens. Results of immune function assays correlated with the biochemical studies: UV-irradiation inhibited the generation of the MLR, but TPA enhanced this reaction, and addition of TPA to mixed lymphocyte cultures with UV-irradiated stimulators did not reverse the UV-induced inhibition. These results suggest that, although the turnover of histocompatibility antigens may be affected by TPA and UV in an antagonistic fashion, additional factors other than the expression of histocompatibility antigens are operating in the inhibition of stimulation of an MLR by UV radiation or its enhancement by TPA.

Minor antigen graft-versus-host reactions revealed in irradiated spleen and popliteal lymph node assays.

The graft-versus-hot (GVH) reaction across minor (non-H-2) histocompatibility barriers was studied in mice, in vivo. To increase GVH potential and to mimic clinical bone marrow transplantation protocols, we modified the popliteal lymph node (PLN) and the splenomegaly assays by irradiating the recipients before they received allogeneic lymphoid cell suspensions. In several combinations across major (H-2), minor (non-H-2) and multiple minor (non-H-2 plus minor lymphocyte stimulation) barriers, increased recipient organ weight (a measure of GVH activity) was seen with irradiated F1 recipients of parental cells. The irradiated splenomegaly (x-splenomegaly) assay was more sensitive than the (x-PLN) assay, but both correlated with in vivo GVH experiments of the P----F1 variety. The x-splenomegaly test indicated histoincompatibility in a system (B10.D2----BALB/c) in which the primary in vitro mixed leukocyte reactions is nonreactive, but in which systemic GVH can be induced. The x-splenomegaly test should be useful in analyzing complex reactions involving minor histocompatibility antigens in vivo.

Recognition and response to alloantigens in vivo. I. Negative and positive selection of MLR reactivity in murine peripheral blood lymphocytes to major histocompatibility complex and Mls antigens.

Specific mixed lymphocyte reaction (MLR) responsiveness to allogeneic major histocompatibility complex (MHC), or minor lymphocyte-stimulating (Mls) determinants, was depleted in the peripheral blood lymphocytes (PBL) obtained from mice 24 to 48 hr after i.v. injection of 5 to 7.5 X 10(7) MHC or Mlsa-incompatible spleen cells, respectively. Results of cell mixture experiments suggest that the generation of suppressor cells was not the explanation for this specific reduction in MLR proliferation occurring with these PBL responder cells. To gain additional insight into parameters involved in the recognition of allodeterminants in vivo, experimental manipulations of the host environment and donor cell inoculum utilized in the negative selection procedure were employed. For example, removal of the spleen in the recipient animal, an anatomic site in which injected allogeneic cells and corresponding host antigen-reactive cells (ARC) are trapped, still permitted the specific depletion in murine PBL of host ARC for donor foreign MHC antigens. This finding may implicate other sites such as the liver where unprimed host alloreactive clones are trapped. In addition, irradiation of allogeneic donor cells significantly reduced their capacity to trap alloreactive T cell clones in vivo, whereas heat treatment of the donor cells completely eliminated this ability, even though the Ia determinants were still expressed, measured by flow cytometry. After the negative selection period, kinetic analysis of proliferation showed that 3, 4, or 5 days after injection of MHC-incompatible allogeneic spleen cells, the PBL of the recipient showed specific hyperresponsiveness to the MHC-haplotype of the donor cells. Interestingly, these primed PBL responder cells had the volume distribution of small resting cells; thoracic duct lymphocytes (TDL), positively selected by adoptive transfer of T cells to irradiated semiallogeneic recipients, are reported to be mainly blast cells. In contrast to the MLR hyperresponsiveness that results from priming with MHC-incompatible splenocytes, PBL, obtained at these later time points from mice primed with Mlsa-incompatible, H-2-compatible splenocytes, showed complete unresponsiveness in MLR to these Mlsa-bearing stimulator cells, as well as some nonspecific reduction in proliferation to MHC-incompatible stimulator cells regardless of their Mls genotype.(ABSTRACT TRUNCATED AT 400 WORDS)

H-2-restricted graft-versus-host reaction: foreign determinants and restriction elements.

Nylon-wool-purified T cells from radiation chimeras cause a lethal graft-versus-host reaction (GVHR) in irradiated, bone-marrow-protected recipients only if the recipient shares a restriction element with the T-cell donor and also expresses antigens foreign to the donor. Class I molecules (H-2K and H-2D) can act as restriction elements, but restriction to class II molecules could not be demonstrated. However, class II molecules as well as H-2K and some non-H-2 determinants could serve as foreign antigens.