Metabolic and physiologic studies of nonimmune lymphoid cells cytotoxic for fibroblastic cells in vitro

An in vitro reaction between mouse lymphoid cells and target fibroblastic cells in wells of microtest plates, which appears to simulate the in vivo rejection of hemopoietic allografts, has been analyzed for metabolic and physiologic requirements. Protein synthesis was required for only the first few hours of culture. Inhibition of RNA synthesis and alteration of cell surface charge with various agents were without obvious effects. Metabolic slowing at 4 °C or deviation of the pH of the culture medium suppressed the reaction. Thymus cells, which are not cytotoxic in this system, significantly but not completely inhibited the cytotoxicity of lymph node cells. Antiserum directed against target cells specifically protected them from the cytotoxic lymphoid cells in the absence of complement.Precursors of cytotoxic lymphoid cells were radiosensitive, unlike the cytotoxic cells themselves. BALB/c anti-C57BL/6 spleen cell serum and ⁸⁹Sr both are able to prevent rejection of marrow allografts in vitro. Lymphoid cells incubated with this antiserum plus complement lost much of their cytotoxicity but were still effective at high ratios of aggressor to target cells. Lymphoid cells of mice treated with ⁸⁹Sr were effectively cytotoxic but lost practically all of their cytotoxicity afer incubation with the antiserum plus complement. Thus, it appears that this reaction detects two different cytotoxic lymphoid cells, either of which can function in vitro. Both cell types may need to cooperate in vivo during marrow allograft rejections.     

Leukocyte integrin-dependent and antibody-independent cytotoxicity of macrophage against allografts

Macrophages (Mphis), but not T cells, infiltrating into the rejection site of either i.p. allografted Meth A (H-2d) fibrosarcoma cells in C57BL/6 (B6) (H-2b) mice or BALB/c (H-2d) skin onto B6 mice are cytotoxic against allografts with H-2d specificity. To determine the mechanisms of specific killing of allografts by allograft-induced Mphi (AIM), we raised approximately 5,000 rat monoclonal antibodies (mAbs) against AIM and selected three of them (R1-73, R2-40 and R1-34), each of which inhibited cytotoxic activity against allografts in a dose-dependent manner. The antigens recognized by R1-73, R2-40 and R1-34 mAbs were defined by immunoprecipitation and Western blot analyses as CD11a, CD18 and CD11b, respectively; and the allografts expressed CD54, a ligand of CD11a or CD11b, suggesting leukocyte integrin-dependent killing. Although Ab-dependent cellular cytotoxicity has been recognized as a mechanism of specific killing by Mphis, the infiltration of AIM into the rejection site of allografts far (approximately 6 days) preceded the appearance of serum IgG Ab specific for the allograft. AIM exhibiting full cytotoxic activity against allografts was also induced in the transplantation site of Fcgamma receptor knockout [(B6x129) F1] mice as well as B10.D2 (H-2 compatible with allograft) and B6-xid (X-linked immunodeficiency with B cell-specific defect) strains of mice. In the latter two strains of mice, the levels of serum IgG Ab to the allograft were negligible. Moreover, the cytotoxic activity of AIM against allografts was not affected by pretreatment of the cells with anti-mouse IgG serum, suggesting Ab-independent cytotoxicity.     

IL‐27 Rα+ cells promoted allorejection via enhancing STAT1/3/5 phosphorylation

Recently, emerging evidence strongly suggested that the activation of interleukin‐27 Receptor α (IL‐27Rα) could modulate different inflammatory diseases. However, whether IL‐27Rα affects allotransplantation rejection is not fully understood. Here, we investigated the role of IL‐27Rα on allorejection both in vivo and in vitro. The skin allotransplantation mice models were established, and the dynamic IL‐27Rα/IL‐27 expression was detected, and IL‐27Rα⁺ spleen cells adoptive transfer was performed. STAT1/3/5 phosphorylation, proliferation and apoptosis were investigated in mixed lymphocyte reaction (MLR) with recombinant IL‐27 (rIL‐27) stimulation. Finally, IFN‐γ/ IL‐10 in graft/serum from model mice was detected. Results showed higher IL‐27Rα/IL‐27 expression in allografted group compared that syngrafted group on day 10 (top point of allorejection). IL‐27Rα⁺ spleen cells accelerated allograft rejection in vivo. rIL‐27 significantly promoted proliferation, inhibited apoptosis and increased STAT1/3/5 phosphorylation of alloreactive splenocytes, and these effects of rIL‐27 could be almost totally blocked by JAK/ STAT inhibitor and anti‐IL‐27 p28 Ab. Finally, higher IL‐27Rα⁺IFN‐γ⁺ cells and lower IL‐27Rα⁺IL‐10⁺ cells within allografts, and high IFN‐γ/low IL‐10 in serum of allorejecting mice were detected. In conclusion, these data suggested that IL‐27Rα⁺ cells apparently promoted allograft rejection through enhancing alloreactive proliferation, inhibiting apoptosis and up‐regulating IFN‐γ via enhancing STAT pathway. Blocking IL‐27 pathway may favour to prevent allorejection, and IL‐27Rα may be as a high selective molecule for targeting diagnosis and therapy for allotransplantation rejection.     

Sequential mechanisms of cyclophosphamide-induced skin allograft tolerance including the intrathymic clonal deletion followed by late breakdown of the clonal deletion

The cellular basis of the transplantation tolerance in a model system of BALB/c (Mls-1b) mice rendered cyclophosphamide (CP)-induced tolerant to DBA/2 (Mls-1a) skin allograft was investigated by assessing V beta 6+ T cells. From our results, three major mechanisms that are essential to the CP-induced skin allograft tolerance were sequentially elucidated. The first mechanism was destruction of donor-Ag-stimulated T cells in the periphery by CP treatment. The second mechanism was intrathymic clonal deletion of donor-reactive T cells, such as V beta 6+ T cells, correlating strongly with intrathymic mixed chimerism. The clonal deletion, however, was not always essential for the maintenance of the skin allografts, because DBA/2 skin survived even after the clonal deletion terminated and V beta 6+ T cells reappeared in the periphery of the recipient BALB/c mice. The third mechanism was generation of tolerogen-specific suppressor T cells, especially in the late stage of the tolerance. In contrast, the clonal anergy that is evidenced by the specific suppression of mixed lymphocyte reaction in the recipient BALB/c mice after injecting with DBA/2 spleen cells alone was not considered as a significant mechanism in prolonging skin allograft survival because such anergic mice showed accelerated rejection of the skin allografts. These results may suggest practical hierarchy of the mechanisms of CP-induced allograft tolerance.     

Regulation of IFN-γ and IL-10 synthesis in vivo, as well as continuous antigen exposure, is associated with tolerance to murine skin allografts

C3H/HEJ mice are rendered hyporesponsive to multiple minor incompatible (B10.BR) skin allografts by pretreatment with irradiated B10.BR lymphoid cells injected via the portal vein, but not the lateral tail vein. As assessed by PCR with lymphocytes taken from grafted mice, or by measuring cytokines in vitro from antigen-restimulated cells, this hyporesponsiveness is associated with decreased mRNA for IFN-γ and IL-2 production, but enhanced mRNA for IL-4 and IL-10 production. In mice given B10.BR cells via the tail vein, but in addition injected every second day with anti-IFN-γ antibody, similar enhanced graft survival (with diminished IFN-γ/IL-2 and enhanced IL-4/IL-10 production) was seen. In a separate study spleen cells from pretreated mice were “parked” in lethally irradiated syngeneic mice for 21 days, along with B10.BR skin grafts to some of the recipients. Only when recipients received this reexposure to B10.BR antigen did adoptively transferred spleen cells show “persistence” of the ability to produce delayed graft rejection and preferential IL-4 production in vitro.     

The use of technetium-99m as a radioisotopic label to assess cell-mediated immunity in vitro

We have developed a radioisotopic microassay of cell-mediated immunity employing target cells prelabeled with technetium-99m (^99mTc), a high specific activity metastable gamma emitter. Labeling kinetics, release and reutilization, subcellular localization, and effects of ^99mTc on DNA and protein synthesis have been investigated. Target cells were optimally labeled with 10 mCi of ^99mTc at 37 °C for 10 min. Cyclic freezing and thawing released less than 10% of total bound radioisotope. Spontaneous leakage of ^99mTc by monolayer cells was negligible over 48 hr and that which was released appeared to be nonreutilizable. Cell fractionation revealed that nuclear, mitochondrial, and microsomal fractions all were labeled with ^99mTc. The incorporation of ³H-thymidine and ³H-amino acids was not impaired in ^99mTc-labeled cells.The alloimmune reactivity of C57BL/6 mice which had received A/J skin allografts was studied by means of the ^99mTc microcytotoxicity assay. Cell-mediated immunity was clearly evident at 7 days postgrafting, peaked at 14 days, and had declined to background levels by 21 days. These findings correlated well with initial acceptance and ultimate rejection of the allografts. The rapid labeling time without dependence upon cell division for incorporation, high specific activity, low spontaneous release, and nonreutilizability are important advantages of ^99mTc over other radionuclides which have been employed in in vitro assays of cell-mediated immunity.     

Restoration of allograft responsiveness in B rats: IV. The divergent migratory behavior of lymphocyte populations mediating cardiac allograft rejection

The T lymphocyte-deprived (B) rat, produced by X-radiation and bone marrow reconstitution of adolescent thymectomized animals, exhibits a true immunological deficit and are unable to reject histoincompatible heterotopic cardiac allografts. A comprehensive survey of lymphocyte traffic in B recipients was performed to correlate the differential potency of specifically sensitized lymphocyte populations mediating re-establishment of immune responsiveness toward the graft, with their migratory and recirculatory behavior. ¹¹¹In-oxine-labeled thoracic duct lymphocytes (TDL) were retained in the peripheral blood and migrated from nonlymphoid organs to lymph nodes of B recipients in higher proportion than any other lymphoid population, particularly splenic lymphocytes (SL). Although all cell groups but TDL were sequestered in the spleen in equal and relatively large numbers, no differences were found between the lymphocyte populations tested in their capacity to accumulate in the grafts. In contrast, an increased avidity in the allograft of ¹²⁵IUdR-labeled TDL and lymph node (LNL) lymphoblasts, as compared to ¹²⁵IUdR-labeled SL, resembles closely the results of functional studies of the differential potency of adoptively transferred cells. We assume that specific cellular interactions induced by the accumulated ¹²⁵IUdR-labeled cells invoke nonspecific mechanisms for the recruitment of other uncommitted ¹¹¹Inlabeled lymphocytes which recirculate between blood and lymph and localize indiscriminately in the allograft amplifying its rejection. The latter lymphocytes can be “armed” by adherent cells residing in the lymphoid organs of graft recipients, particularly spleen, and subsequently increase the penetration of the foreign tissue. When radiolabeled lymphocytes were traced in B recipients experiencing rejection of their allografts following transfer of sensitized cells plus lymphokine, their migration patterns as well as blastogenic response in B hosts were similar to those observed during acute rejection of cardiac allografts in unmodified hosts. Thus the similarities between the rejection network brought by alloimmune cells into otherwise unresponsive animals and immunocompetent animals able to reject their grafts are stressed.     

Intact B-cell activity is essential for complete expression of experimental allergic encephalomyelitis in Lewis rats

The mechanisms of the inhibitory effect of the serum thymic factor (FTS) on allograft immunity have been studied on both cellular and humoral immune responses of skin allografted mice. FTS-induced suppression of allogeneic skin graft rejection was correlated with a transient diminution of in vivo alloreactive CTL production in the spleen, whereas the generation of allo-anti-H-2 antibodies was not affected. The involvement of suppressor cells in the effect of FTS was supported by the observation that irradiated spleen cells from FTS-treated recipients (bearing a 9-day allograft) suppressed the in vitro CTL generation.     

Th1 to Th2 immune deviation facilitates,but does not cause,islet allograft tolerance in mice

It has been reported that Th1 to Th2 immune deviation effectively promotes peripheral tolerance in situations involving a limited T cell clone size, such as T cell-dependent autoimmunity and transplantation across minor, but not major, histocompatibility barriers. In this study, we tested the hypothesis that while Th1 to Th2 immune deviation fails to induce tolerance in the MHC-mismatched islet allograft model, it may promote a state that is permissive for tolerance induction. Here, we report that anti-IL-12 did not prevent acute rejection of islet allografts when administered alone. In conjunction with CTLA4/Fc, however, anti-IL-12 greatly facilitated long-term engraftment in three MHC-mismatched strain combinations. Similarly, while non-cytolytic IL-4/Fc, a long-lasting form of IL-4, did not prevent acute graft rejection when administered alone, a low, but not a high, dose of IL-4/Fc synergized with CTLA4/Fc in inducing significant levels of islet allograft tolerance. Moreover, by using a skin allograft adoptive transfer model, we show that these effects induced by anti-IL-12 and IL-4/Fc treatment were associated with an enhancement of the suppressive properties of CD4⁺CD25⁺ regulatory T cells. Thus, anti-IL-12 and low-dose IL-4/Fc facilitate, but do not cause, islet allograft tolerance in mice by increasing the immunosuppressive potency of CD4⁺CD25⁺ regulatory T cells.     

I-TAC is a dominant chemokine in controlling skin intragraft inflammation via recruiting CXCR3 cells into the graft

Chemokines play a critical role in the acute transplant rejection. In order to provide an overview of the chemokine expression during the course of acute allograft rejection, the intragraft expression profile of 11 chemokines representative of all four chemokine subfamilies was analyzed in a murine skin transplantation model of acute rejection. It was found that RANTES/CCL5, TARC/CCL17 and FKN/CX₃CL1 were expressed at equivalent levels in iso- and allografts. However, the other eight chemokines expression was up-regulated to some extent in allograft compared with that in isograft. The levels of MIP-1α/CCL3, MIP-3α/CCL20 and CTACK/CCL27 were progressively increased from early stage (day 3 post-transplantation) to late stage (day 11). Mig/CXCL9, IP-10/CXCL10, I-TAC/CXCL11, CXCL16 and LTN/XCL1 expression was elevated at middle stage (day 7), and peaked at late stage. Among the up-regulated chemokines, I-TAC was the most obviously elevated chemokine. Therefore, the effect of I-TAC on the skin acute allograft rejection was evaluated. Block of I-TAC by the intradermal injection of anti-I-TAC monoclonal antibody (mAb) reduced the number of CXCR3⁺ cells in skin allograft and significantly prolonged the skin allograft survival. The mAb treatment did not influence the proliferation of the intragraft infiltrating cells in response to the allogeneic antigens, but significantly decreased the number of the infiltrating cells and consequently lowered the secretion of IFN-γ and TNF-α. These data indicate I-TAC might be a dominant chemokine involved in the intradermal infiltration and I-TAC-targeted intervening strategies would have potential application for the alleviation of acute transplant rejection.     

Rejection of skin allografts by CD4+ T cells is antigen-specific and requires expression of target alloantigen on Ia- epidermal cells

The effector mechanism of skin allograft rejection has been characterized as Ag specific, rejecting cells that express the target alloantigen but sparing those that do not. However, the rejection of MHC class II disparate skin grafts, in which very few cells (Langerhans cells) actually express the target Ia Ag could conceivably proceed by either one of two distinct rejection mechanisms. One possibility is that Ia- cells are destroyed by a sequence of events in which CD4+ T cells, activated by Ia+ LC, elaborate soluble factors that are either directly cytolytic or that recruit and activate non-specific effector cells. The alternative possibility is that activated CD4+ T cells elaborate soluble factors which induce Ia expression on Ia- cell populations, and that these Ia+ cells are subsequently destroyed by effector cells specific for the induced Ia alloantigens. We found that rejection of Ia+ LC was not of itself sufficient to cause rejection of skin grafts, indicating that skin allograft rejection is contingent on the destruction not only of LC but of other graft cell populations as well. We then investigated whether CD4+ T cells rejected allogeneic skin grafts in an antigen specific fashion. To do so, we engrafted immunoincompetent H-2b nude mice with trunk skin grafts from B6----A/J allophenic mice because such skin is composed of mutually exclusive cell populations expressing either H-2a or H-2b histocompatibility Ag, but not both. The engrafted mice were subsequently reconstituted with H-2b CD4+ T cells. The CD4+ T cells destroyed keratinocytes of A/J origin but spared keratinocytes of B6 origin, even though neither cell population constitutively expresses target IAk alloantigen. The targeted rejection of A/J keratinocytes but not of B6 keratinocytes indicates that the target Ia alloantigen must have been induced on Ia- A/J keratinocytes, rendering them susceptible to destruction by anti-Iak-specific CD4+ effector cells. These data demonstrate that CD4+ T cell rejection of skin allografts is mediated by Ag-specific CD4+ cytolytic T cells and hence, requires the induction of target Ia alloantigens on epidermal cells within the graft.     

CD4 T cell-mediated rejection of cardiac allografts in B cell-deficient mice

CD4 T cell-dependent mechanisms promoting allograft rejection include expression of inflammatory functions within the graft and the provision of help for donor-reactive CD8 T cell and Ab responses. These studies tested CD4 T cell-mediated rejection of MHC-mismatched cardiac allografts in the absence of both CD8 T and B lymphocytes. Whereas wild-type C57BL/6 recipients depleted of CD8 T cells rejected A/J cardiac grafts within 10 days, allografts were not rejected in B cell-deficient B6.muMT(-/-) recipients depleted of CD8 T cells. Isolated wild-type C57BL/6 and B6.muMT(-/-) CD4 T cells had nearly equivalent in vivo alloreactive proliferative responses. CD4 T cell numbers in B6.muMT(-/-) spleens were 10% of that in wild-type mice but were only slightly decreased in peripheral lymph nodes. CD8 T cell depletion did not abrogate B6.muMT(-/-) mice rejection of A/J skin allografts and this rejection rendered these recipients able to reject A/J cardiac allografts. Redirection of the alloimmune response to the lymph nodes by splenectomy conferred the ability of B6.muMT(-/-) CD4 T cells to reject cardiac allografts. These results indicate that the low number of splenic CD4 T cells in B6.muMT(-/-) mice underlies the inability to reject cardiac allografts and this inability is overcome by diverting the CD4 T cell response to the peripheral lymph nodes.     

B7-H1-induced apoptosis as a mechanism of immune privilege of corneal allografts

The programmed death-1 (PD-1) costimulatory pathway has been demonstrated to play a role in the regulation of immune responses and peripheral tolerance. We investigated the role of this pathway in establishing an immune privilege status of corneal allografts in mice. B7-H1, but not B7-DC or PD-1, was expressed constitutively in the eye, i.e., cornea, iris-ciliary body, and retina. After corneal allografting, PD-1(+)CD4(+) T cells infiltrated and adhered with B7-H1(+) corneal endothelium. Blockade of PD-1 or B7-H1, but not B7-DC, led to accelerated corneal allograft rejection. In B7-H1-expressing corneal allografts, apoptosis of the infiltrating PD-1(+)CD4(+) or CD8(+) T cells was observed, after which there was allograft acceptance. In contrast, B7-H1 blockade suppressed apoptosis of infiltrating PD-1(+) T cells, which led to allograft rejection. In vitro, destruction of corneal endothelial cells by alloreactive T cells was enhanced when the cornea was pretreated with anti-B7-H1 Ab. This is the first demonstration that the constitutive expression of B7-H1 plays a critical role in corneal allograft survival. B7-H1 expressed on corneal endothelial cells maintains long-term acceptance of the corneal allografts by inducing apoptosis of effector T cells within the cornea.     

Effector mechanisms in allograft rejection. II. Density, electrophoresis, and size fractionation of allograft-infiltrating cells demonstrating several classes of killer cells.

An analysis of killer cells infiltrating “sponge-matrix” allografts during rejection has been performed by preparative fractionation by density centrifugation, velocity sedimentation, and free flow cell electrophoresis and by the use of heterologous anti-T-cell sera. At the peak of rejection, 7 to 8 days after transplantation, the allograft is infiltrated by several classes of killer cells, most notably by non-T lymphocytes, monocytes/macrophages, and T lymphocytes. The predominant cell types capable of performing in vitro lysis of relevant target cells appeared to be monocytes and non-T lymphocytes. T lymphocytes formed only a minority of the killer cells at this stage of the response. In contrast, as also documented earlier, the predominant killer cells in the regional lymph nodes and the spleen of the graft recipient mice were T lymphocytes (blasts).     

Outcome of adrenal tissue fragments allotransplantation: The impact of cryopreservation

Cryopreservation is thought to have the potential to preserve tissue for transplantation. In addition, it can also be used for decreasing tissue immunogenicity, which might be important for prolonging allograft survival. In the present study we examined the impact of cryopreservation at various cooling rates on the outcome of allotransplantation of murine adrenal tissue fragments (ATFr). ATFr were cryopreserved with a cooling rate at 1; 10; 40 and more than 100 °C/min. After thawing it was found that the number of the cells expressing markers of dendritic cells (CD11c) and macrophages (CD11b) in the suspension obtained from ATFr decreased with increasing cooling rate. After allotransplantation the survival rates of adrenalectomized mice and the blood serum levels of corticosterone were higher in recipients of cryopreserved ATFr. By immunohistochemistry, cryopreserved allografts displayed a decreased infiltration by CD4⁺ and CD8⁺ T-lymphocytes as compared to fresh grafts. These findings suggest that cryopreserved allografts cause a less severe rejection by decreasing graft immunogenicity.     

Outcome of adrenal tissue fragments allotransplantation: The impact of cryopreservation

Cryopreservation is thought to have the potential to preserve tissue for transplantation. In addition, it can also be used for decreasing tissue immunogenicity, which might be important for prolonging allograft survival. In the present study we examined the impact of cryopreservation at various cooling rates on the outcome of allotransplantation of murine adrenal tissue fragments (ATFr). ATFr were cryopreserved with a cooling rate at 1; 10; 40 and more than 100 °C/min. After thawing it was found that the number of the cells expressing markers of dendritic cells (CD11c) and macrophages (CD11b) in the suspension obtained from ATFr decreased with increasing cooling rate. After allotransplantation the survival rates of adrenalectomized mice and the blood serum levels of corticosterone were higher in recipients of cryopreserved ATFr. By immunohistochemistry, cryopreserved allografts displayed a decreased infiltration by CD4⁺ and CD8⁺ T-lymphocytes as compared to fresh grafts. These findings suggest that cryopreserved allografts cause a less severe rejection by decreasing graft immunogenicity.     

Peptide nucleic acid antisense prolongs skin allograft survival by means of blockade of CXCR3 expression directing T cells into graft

CXCR3, predominantly expressed on memory/activated T cells, is a receptor for both IFN-gamma-inducible protein 10/CXC chemokine ligand (CXCL)10 and monokine induced by IFN-gamma/CXCL9. It was reported that CXC chemokines IFN-gamma-inducible protein 10/CXCL10 and monokine induced by IFN-gamma/CXCL9 play a critical role in the allograft rejection. We report that CXCR3 is a dominant factor directing T cells into mouse skin allograft, and that peptide nucleic acid (PNA) CXCR3 antisense significantly prolongs skin allograft survival by means of blockade of CXCR3 expression directing T cells into allografts in mice. We found that CXCR3 is highly up-regulated in spleen T cells and allografts from BALB/c recipients by day 7 of receiving transplantation, whereas CCR5 expression is moderately increased. We designed PNA CCR5 and PNA CXCR3 antisenses, and i.v. treated mice that received skin allograft transplantations. The PNA CXCR3 at a dosage of 10 mg/kg/day significantly prolonged mouse skin allograft survival (17.1 +/- 2.4 days) compared with physiological saline treatment (7.5 +/- 0.7 days), whereas PNA CCR5 (10 mg/kg/day) marginally prolonged skin allograft survival (10.7 +/- 1.1 days). The mechanism of prolongation of skin allograft survival is that PNA CXCR3 directly blocks the CXCR3 expression in T cells, which is responsible for directing T cells into skin allograft to induce acute rejection, without interfering with other functions of the T cells. These results were obtained at mRNA and protein levels by flow cytometry and real-time quantitative RT-PCR technique, and confirmed by chemotaxis, Northern and Western blot assays, and histological evaluation of skin grafts. The present study indicates the therapeutic potential of PNA CXCR3 to prevent acute transplantation rejection.     

Donor T cell activation initiates small bowel allograft rejection through an IFN-gamma-inducible protein-10-dependent mechanism

The poor success in controlling small bowel (SB) allograft rejection is partially attributed to the unique immune environment in the donor intestine. We hypothesized that Ag-induced activation of donor-derived T cells contributes to the initiation of SB allograft rejection. To address the role of donor T cell activation in SB transplantation, SB grafts from DO11.10 TCR transgenic mice (BALB/c, H-2L(d+)) were transplanted into BALB/c (isografts), or single class I MHC-mismatched (L(d)-deficient) BALB/c H-2(dm2) (dm2, H-2L(d-)) mutant mice (allografts). Graft survival was followed after injection of control or antigenic OVA(323-339) peptide. Eighty percent of SB allografts developed severe rejection in mice treated with antigenic peptide, whereas <20% of allografts were rejected in mice treated with control peptide (p < 0.05). Isografts survived >30 days regardless of OVA(323-339) administration. Activation of donor T cells increased intragraft expression of proinflammatory cytokine (IFN-gamma) and CXC chemokine IFN-gamma-inducible protein-10 mRNA and enhanced activation and accumulation of host NK and T cells in SB allografts. Treatment of mice with neutralizing anti-IFN-gamma-inducible protein-10 mAb increased SB allograft survival in Ag-treated mice (67%; p < 0.05) and reduced accumulation of host T cells and NK cells in the lamina propria but not mesenteric lymph nodes. These results suggest that activation of donor T cells after SB allotransplantation induces production of a Th1-like profile of cytokines and CXC chemokines that enhance infiltration of host T cells and NK cells in SB allografts. Blocking this pathway may be of therapeutic value in controlling SB allograft rejection.     

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.