Mechanisms maintaining antibody-induced enhancement of allografts. II. Mediation of specific suppression by short lived CD4+ T cells

In DA rats grafted with PVG hearts, the injection of 1 ml of Wistar-Furth x DA)F1 anti-PVG serum on the day of grafting prevents rejection and induces a state of specific unresponsiveness. An adoptive transfer assay was used to test the capacity of T cell subsets, taken from rats given enhancing serum, to either restore rejection or to transfer unresponsiveness to syngeneic hosts irradiated with 9 Gy and grafted with donor (PVG) or third party (Wistar-Furth) hearts. W3/25+ (CD4+) cells from these animals retained some capacity to restore rejection until 50 days posttransplant, after which they invariably failed to restore PVG graft rejection but retained the capacity to effect Wistar-Furth rejection. At this time CD4+ cells were also capable of inhibiting naive but not specifically sensitized CD4+ cells capacity to restore PVG graft rejection in irradiated hosts. The development of CD4+ suppressor cells was concurrent with the appearance of clinically evident unresponsiveness in the host. MRC Ox8+ (CD8+) cells from enhanced rats when mixed with naive CD4+ cells delayed rejection in adoptive recipients but did not reestablish unresponsiveness. Paradoxically, the CD4+ cells that transfer unresponsiveness to the adoptive host proliferate such as normal cells in MLC to both donor and third party alloantigen. Unfractionated cells, CD4+ or CD8+ cells did not proliferate to relevant idiotype in vitro. The CD4+ cells after 3 days in culture, with either alloantigen or idiotype-bearing stimulator cells, lost their capacity to suppress in the adoptive transfer assay. The maintenance of specific unresponsiveness was thus shown to be due to a CD4+ suppressor T cell whose function was lost in culture, and therefore could not be detected in MLC or idiotype assays.     

Cellular basis of allograft rejection in vivo. V. Examination of the mechanisms responsible for the differing efficacy of monoclonal antibody to CD4+ T cell subsets in low- and high-responder rat strains

MRC OX35, an anti-CD4 mAb, was used to treat high responder Wistar Furth (W/F) (RT1u) and low responder DA (RT1a) rats which had been grafted with directly vascularized hearts from PVG (RT1c) rats across a full MHC plus non-MHC incompatibility. Four doses of mAb at 7 mg/kg given in the first 2 wk postgrafting induced indefinite graft survival (greater than 150 days) in DA hosts, but only delayed rejection to 18 to 42 days in W/F as compared to rejection times of 6 to 8 days in untreated rats. The extension of MRC OX35 treatment to 6 wk in W/F rats induced indefinite graft survival in three of six rats. During treatment MRC OX35 therapy only partially depleted CD4+ cells, and all circulating CD4+ cells were coated with MRC OX35. The capacity of naive CD4+ and CD8+ cells from W/F and DA to be activated to PVG alloantigen was compared both in vitro in an MLC assay and in vivo by an adoptive transfer assay of their capacity to restore rejection of PVG heart grafts in irradiated syngeneic hosts. CD4+ cells from both W/F and DA proliferated in MLC and restored graft rejection. W/F CD8+ cells both proliferated in MLC and restored rejection, but DA CD8+ cells neither proliferated nor reconstituted rejection. Examination of lymphocytes from MRC OX35 treated hosts with long-surviving grafts showed that they were neither depleted of CD4+ T cells nor did they lack the capacity to proliferate to PVG Ag in MLC, this response being similar to that to third-party Ag or by naive lymphocytes. Compared to first-set rejection, PVG skin graft rejection was delayed 2 to 3 days in W/F and 10 to 12 days in DA rats with long-surviving grafts after MRC OX35 therapy, whereas they rejected third-party skin grafts in first-set tempo. These studies show that differences in graft survival in anti-CD4 treated low and high responder strains may be due to the inherent capacity of CD8+ cells to be activated to effect rejection independent of CD4+ cells in W/F but not in DA. In those hosts that accept grafts, there is no evidence of clonal deletion, but there appears to be a form of unresponsiveness akin to that induced in adult rats by other immunosuppressive therapies that protects the graft from rejection.     

Critical role of CD4 help in CD154 blockade-resistant memory CD8 T cell activation and allograft rejection in sensitized recipients

Allograft rejection in sensitized recipients remains the major problem in clinical organ transplantation. We have developed a donor-type skin-sensitized mouse cardiac allograft model (BALB/c-->C57BL/6) in which both rejection (<5 days) and alloreactive CD8 activation are resistant to CD154 blockade. First, we attempted to elucidate why CD154 blockade fails to protect cardiac grafts in sensitized recipients. The gene array analysis has revealed that treatment with anti-CD154 mAb (MR1) had distinctive impact on host immunity in naive vs sensitized animals. Unlike in naive counterparts, host sensitization mitigated the impact of CD154 blockade on critical immune signaling pathways. Indeed, we identified 3234 genes in cardiac grafts that were down-regulated by MR1 in naive (at least 5-fold), but remained unaffected in sensitized hosts. Moreover, MR1 treatment failed to prevent accumulation of CD4 T cells in cardiac allografts of sensitized recipients. Then, to determine the role of CD4 help in CD154 blockade-resistant immune response, we used CD4-depleting and CD4-blocking Ab, in conjunction with MR1 treatment. Our data revealed that CD154 blockade-resistant CD8 activation in sensitized mice was dependent on CD4 T cells. In the absence of CD4 help, CD154 blockade prevented differentiation of alloreactive CD8 T cells into CTL effector/memory cells and abrogated acute rejection (cardiac graft survival for >30 days), paralleled by selective target gene depression at the graft site. These results provide the rationale to probe potential synergy of adjunctive therapy targeting CD4 and CD154 to overcome graft rejection in sensitized recipients.     

W3/25+ T cells mediate the induction of immunologic unresponsiveness in enhanced rat recipients of cardiac allografts

Cellular suppressor mechanisms developing during the induction of immunologic enhancement were studied in LEW rats immunized actively with BN spleen cells and passively with LEW anti-BN hyperimmune serum 11 and 10 days before receiving a (LEW X BN)F1 cardiac allograft, respectively. With this regimen, graft survival is prolonged from 7.4 +/- 0.5 days in unmodified, acutely rejecting hosts to 25 +/- 12 days in enhanced recipients, with one-third of the grafts surviving indefinitely. To test for suppressor capacities, 60 X 10(6) splenic T helper/inducer (W3/25+) and T suppressor/cytotoxic (OX8+) cells were adoptively transferred 7 and 14 days after transplantation either into unmodified syngeneic LEW animals that received (LEW X BN)F1 test grafts 24 hr later or into T cell-deprived B rats with indefinitely functioning heart transplants that were reconstituted with sensitized lymph node cells (100 X 10(6). W3/25+ T cells harvested on days 7 and 14 from enhanced recipients prolonged test graft survival in unmodified hosts (13.1 +/- 2.3 and 13.3 +/- 1.3 days, respectively, p less than 0.001) and delayed rejection in reconstituted B rats from 6.7 +/- 0.5 to 18.2 +/- 6.5 and 23.3 +/- 5.8 days, respectively (p less than 0.001). OX8+ and B lymphocytes had no suppressor activity. However, enzymatic stripping of the surfaces of W3/25+ cells abrogated suppressor function. Similarly, after i.p. treatment with cyclophosphamide, W3/25+ T cells lost their suppressor properties. Lack of donor specific but not third party alloaggressiveness was demonstrated by the profoundly diminished ability of W3/25+ lymphocytes from enhanced hosts to recreate rejection in nonreconstituted B rats, even when exogenous interleukin 2 was administered. After pronase treatment, however, W3/25+ T cells were capable of inducing immunoresponsiveness at a tempo similar to naive T helper cells (31.5 +/- 12.5 vs 32.8 +/- 7.9). Thus, the present studies provide evidence for the development of a specific W3/25+ suppressor cell in the induction of active and passive enhancement. Coincident abrogation of specific T effector alloaggressiveness is apparently mediated by surface-blocking factors.     

Bone marrow-derived T lymphocytes responsible for allograft rejection

Lethally irradiated mice reconstituted with syngeneic bone marrow cells were grafted with allogeneic skin grafts 6-7 weeks after irradiation and reconstitution. Mice with intact thymuses rejected the grafts whereas the mice thymectomized before irradiation and reconstitution did not. Thymectomized irradiated mice (TIR mice) reconstituted with bone marrow cells from donors immune to the allografts rejected the grafts. Bone marrow cells from immunized donors, pretreated with Thy 1.2 antibody and C', did not confer immunity to TIR recipients. To determine the number of T lymphocytes necessary for the transfer of immunity by bone marrow cells from immunized donors, thymectomized irradiated mice were reconstituted with nonimmune bone marrow cells treated with Thy 1.2 antibody and C' and with various numbers of splenic T lymphocytes from nonimmune and immune donors. Allogeneic skin graft rejection was obtained with 10(6) nonimmune or 10(4) immune T cells. The effect of immune T cells was specific: i.e., immune T cells accelerated only rejection of the relevant skin grafts whereas against a third-party skin grafts acted as normal T lymphocytes.     

The peripheral nerve allograft: an assessment of regeneration across nerve allografts in rats immunosuppressed with cyclosporin A

Lewis rats (RT1(1] were the recipients of 3-cm nerve grafts from syngeneic Lewis donors or allogeneic ACI (RT1a) donors. Microneurosurgical repair of the nerve graft to the transected sciatic nerve of the recipient animal was performed with 10-0 epineurial sutures. Recipients were randomly allocated to cyclosporin A (CsA) immunosuppressed or untreated groups. Cyclosporin A was administered in the minimal effective dosage to prevent nerve allograft rejection across this major histocompatibility disparity (5 mg/kg per day). Nerve regeneration across the nerve grafts was assessed by sciatic function index (SFI) and toe spread index (TSI) determinations serially and by electrophysiologic, histologic, and morphologic assessments 14 weeks after engraftment. Sciatic nerve regeneration across allogeneic nerve grafts in cyclosporin A immunosuppressed recipients was significantly superior compared to the untreated controls (p less than 0.008) and not significantly different from that across the syngeneic control animals.     

T cell subsets in allograft rejection. In situ characterization of T cell subsets in human skin allografts by the use of monoclonal antibodies

We have provided evidence that both major T cell subsets, T4-positive (helper/inducer) and T8-positive (cytotoxic/suppressor), infiltrate human skin allografts. Overall, and in the graft dermis and graft bed, T4-positive cells were predominant (1.5 to 3 times more numerous than T8-positive cells). In contrast, T8-positive cells were relatively more numerous in the epidermis and hair follicles. Rejection probably proceeded by two apparently independent pathways: 1) direct contact killing of graft epithelial cells, presumably by immunologically specific T8-positive cytotoxic cells, and 2) injury of microvascular endothelium of both the graft and graft bed with secondary graft infarction. Although important in first set skin allograft rejection, the mechanism of the second type of killing is uncertain. T4-positive cells were probably involved, as evidenced by their greater numbers; furthermore, studies in mice have shown that transfused helper/inducer cells are able to effect first-set skin graft rejection. It remains to be determined whether T4-positive cells act alone or cooperate with other cells to destroy vessels and bring about graft rejection. Langerhans cells were recognized in epithelial and dermal compartments of both allografts and autografts by their reactivity with anti-T6 and anti-Ia antibodies. We could not determine whether such cells in allografts were of host or donor origin.     

Prolonged Graft Survival in Older Recipient Mice Is Determined by Impaired Effector T-Cell but Intact Regulatory T-Cell Responses

Elderly organ transplant recipients represent a fast growing segment of patients on the waiting list. We examined age-dependent CD4⁺ T-cell functions in a wild-type (WT) and a transgenic mouse transplant model and analyzed the suppressive function of old regulatory T-cells. We found that splenocytes of naïve old B6 mice contained significantly higher frequencies of T-cells with an effector/memory phenotype (CD4⁺CD44^highCD62L^low). However, in-vitro proliferation (MLR) and IFNγ-production (ELISPOT) were markedly reduced with increasing age. Likewise, skin graft rejection was significantly delayed in older recipients and fewer graft infiltrating CD4⁺T-cells were observed. Old CD4⁺ T-cells demonstrated a significant impaired responsiveness as indicated by diminished proliferation and activation. In contrast, old alloantigen-specific CD4⁺CD25⁺FoxP3⁺ T-cells demonstrated a dose-dependent well-preserved suppressor function. Next, we examined characteristics of 18-month old alloreactive T-cells in a transgenic adoptive transfer model. Adoptively transferred old T-cells proliferated significantly less in response to antigen. Skin graft rejection was significantly delayed in older recipients, and graft infiltrating cells were reduced. In summary, advanced recipient age was associated with delayed acute rejection and impaired CD4⁺ T-cell function and proliferation while CD4⁺CD25⁺FoxP3⁺ T-cells (Tregs) showed a well-preserved function.     

Transfer of cell-mediated hyperacute rejection reaction: The role of active sensitization

The transfer of lymph node cells draining graft sites of allogeneic murine skin results in adoptive immunization of syngeneic recipients, as per hyperacute rejection of allogeneic test skin grafts. The transfer of spleen cells from mice sensitized by i.p. injection of allogeneic cells does not have this result unless the cells undergo a secondary in vitro sensitization. The resultant hyperacute rejection is due in part to adoptive immunization via the spleen cells primed during the in vivo sensitization and rendered transfer effective by the in vitro exposure; in part it is due to active sensitization by carried-over antigen from the in vitro exposure. It follows that the transfer effect of spleen cells sensitized in vivo and in vitro is only in part abrogated by exposure to α-Thy. 1 serum and complement.     

Antibody-mediated rejection of cardiac allografts in CCR5-deficient recipients

Rejected MHC-mismatched cardiac allografts in CCR5(-/-) recipients have low T cell infiltration, but intense deposition of C3d in the large vessels and capillaries of the graft, characteristics of Ab-mediated rejection. The roles of donor-specific Ab and CD4 and CD8 T cell responses in the rejection of complete MHC-mismatched heart grafts by CCR5(-/-) recipients were directly investigated. Wild-type C57BL/6 and B6.CCR5(-/-) (H-2(b)) recipients of A/J (H-2(a)) cardiac allografts had equivalent numbers of donor-reactive CD4 T cells producing IFN-gamma, whereas CD4 T cells producing IL-4 were increased in CCR5(-/-) recipients. Numbers of donor-reactive CD8 T cells producing IFN-gamma were reduced 60% in CCR5(-/-) recipients. Day 8 posttransplant serum titers of donor-specific Ab were 15- to 25-fold higher in CCR5(-/-) allograft recipients, and transfer of this serum provoked cardiac allograft rejection in RAG-1(-/-) recipients within 14 days, whereas transfer of either serum from wild-type recipients or immune serum from CCR5-deficient recipients diluted to titers observed in wild-type recipients did not mediate this rejection. Wild-type C57BL/6 and B6.CCR5(-/-) recipients rejected A/J cardiac grafts by day 11, whereas rejection was delayed (day 12-60, mean 21 days) in muMT(-/-)/CCR5(-/-) recipients. These results indicate that the donor-specific Ab produced in CCR5(-/-) heart allograft recipients is sufficient to directly mediate graft rejection, and the absence of recipient CCR5 expression has differential effects on the priming of alloreactive CD4 and CD8 T cells.     

Evidence for extrathymic development of TNK cells. NK1+ CD3+ cells responsible for acute marrow graft rejection are present in thymus-deficient mice.

The predominant mechanism responsible for acute specific rejection of allogeneic and parental bone marrow by irradiated mice is due to a cell (TNK) that expresses the NK cell surface markers NK1 and ASGM1 as well as TCR. Here we analyze the question as to whether TNK cells require a functional thymus for their development. Using adoptive cell transfer assays, evidence is presented that, as is the case in normal mice, NK1+ CD3+ effector cells are responsible for rejection in thymus-deficient nude mice and that the specificity of rejection is indistinguishable from that of normal mice. To reveal the presence of TNK cells in the spleen of nude mice, double staining for NK1 and CD3 followed by FACS analysis was done. It is shown that NK1+ CD3+ cells are present in the spleens of nude but not euthymic mice, suggesting that the lack of a functional thymus stimulates either Ag expression or the number of TNK cells. In support of this finding, the treatment of irradiated marrow reconstituted mice with cyclosporin A leads to the appearance of TNK cells in the spleen. The relative efficiency of spleen cells from nude and cyclosporin A-treated mice to transfer resistance in adoptive cell transfers was assessed and found to be higher than that of normal spleen, consistent with the higher frequency of these cells in thymus-defective mice. The fate of NK1+ CD3+ cells subsequent to stimulation with an allogeneic marrow graft indicates that these cells proliferate in nude mice without gaining cytolytic activity. In euthymic mice, however, NK1+ CD3+ cells appear transiently but disappear in favor of CD4+ and CD8+ cells that proliferate in response to an allogeneic marrow graft. The CD8+ cells express cytolytic activity with specificity similar to that of the acute rejection mechanism, consistent with the suggestion that TNK cells differentiate into CD8+ killer cells. The reason why TNK cells in nude mice fail to differentiate into CD8+ CTL is explained by the lack of Th cells.     

Allograft rejection by primed/memory CD8+ T cells is CD154 blockade resistant: therapeutic implications for sensitized transplant recipients

We have shown that CD8(+) CTLs are the key mediators of accelerated rejection, and that CD8(+) T cells represent the prime targets of CD154 blockade in sensitized mouse recipients of cardiac allografts. However, the current protocols require CD154 blockade at the time of sensitization, whereas delayed treatment fails to affect graft rejection in sensitized recipients. To elucidate the mechanisms of costimulation blockade-resistant rejection and to improve the efficacy of CD154-targeted therapy, we found that alloreactive CD8(+) T cells were activated despite the CD154 blockade in sensitized hosts. Comparative CD8 T cell activation study in naive vs primed hosts has shown that although both naive and primed/memory CD8(+) T cells relied on the CD28 costimulation for their activation, only naive, not primed/memory, CD8(+) T cells depend on CD154 signaling to differentiate into CTL effector cells. Adjunctive therapy was designed accordingly to deplete primed/memory CD8(+) T cells before the CD154 blockade. Indeed, unlike anti-CD154 monotherapy, transient depletion of CD8(+) T cells around the time of cardiac engraftment significantly improved the efficacy of delayed CD154 blockade in sensitized hosts. Hence, this report provides evidence for 1) differential requirement of CD154 costimulation signals for naive vs primed/memory CD8(+) T cells, and 2) successful treatment of clinically relevant sensitized recipients to achieve stable long term graft acceptance.     

Effector mechanisms in cyclosporine A-induced syngeneic graft-versus-host disease. Role of CD4+ and CD8+ T lymphocyte subsets

Syngeneic graft-versus-host disease (SGVHD) is a T cell-mediated autoimmune disease occurring postsyngeneic bone marrow transplantation and the administration of the potent immunosuppressive agent, cyclosporine A. Paradoxically, cyclosporine A disrupts the immunologic homeostasis governing self-tolerance. Our studies using an adoptive transfer model attempted to identify effector mechanisms associated with the autoimmune disease. Both CD4+ and CD8+ splenic T cells isolated from autoimmune donors were required for the adoptive transfer of active disease into lethally irradiated secondary recipients reconstituted with normal bone marrow. Doses of more than 5 x 10(6) of nylon wool depleted splenocytes from autoimmune donors effectively transferred disease into lethally irradiated secondary recipients. Splenocytes that are T cell depleted or CD4(+)-enriched cells did not elicit disease upon adoptive transfer. Nylon wool fractionated CD8+ splenocytes also failed to adoptively transfer disease unless high doses (greater than or equal to 30 x 10(6)) were used. The disease transferred with the CD8+ subset presented as acute type SGVHD and was self-limiting. The recombination of the individually isolated T cell subsets not only restored but also enhanced immune reactivity upon adoptive transfer. Moreover, use of the recombined subsets resulted in progressive disease with the development of chronic type SGVHD. The titration of each subset to the other suggested that a minimal number of CD4+ T cells was required to potentiate the CD8+ autoreactive cells in vivo. Further analysis of the helper cell involved demonstrated that it had a CD4+ CD45r- phenotype, characteristic of an amplifying helper cell population. Administration of IL-2 did not substitute for CD4+ Th cells but yet amplified the activity of unfractionated cells or recombined subsets implicating the role of other factors in the pathogenesis of SGVHD. Delineation of the effector mechanisms involved in SGVHD is critical in determining the underlying events that trigger either the production of autoreactive cells or the perturbation of the regulation of these autoreactive cells, culminating in autoimmunity.     

An absence of T cells in murine bone marrow allografts leads to an increased susceptibility to rejection by natural killer cells and T cells

The mechanisms behind the increased incidence of marrow graft failure in recipients that receive allogeneic marrow depleted of T cells were studied. Recipient mice were lethally irradiated and challenged with bone marrow cells (BMC) from C.B-17 +/+ (+/+) donors. Radioisotope 125IUdR incorporation was assessed 5 to 7 days after transfer to determine the extent of engraftment. Some groups received BMC in which the T cells were removed by treatment with antibody and C. In addition, some groups received BMC from T cell-deficient C.B-17 scid/scid (SCID) mice to determine the postulated need for donor T cells in hematopoiesis and engraftment. In a model system that distinguishes between possible host NK cell and radioresistant T cell-mediated rejection of marrow allografts, it was determined that the absence of donor T cells in a marrow graft does not affect engraftment in syngeneic recipients. However, both host NK cell and radioresistant T cell rejection was markedly enhanced when SCID BMC or BMC from C.B-17 +/+ donors that had T cells removed by antibody and complement were infused into irradiated allogeneic recipients. Furthermore, the addition of alloreactive thymocytes as a source of T cells could abrogate this increased susceptibility of the BMC to host rejection mechanisms. As determined by histology and 59Fe uptake, the addition of thymocytes resulted in enhanced erythropoiesis. These results suggest that the increased incidence of marrow graft failure when BMC depleted of T cells are used is a result of active rejection by host effector cells and that the adverse effect of marrow T cell depletion can be reversed by the addition of thymocytes.     

Inhibition of antiskin allograft immunity induced by infusions with photoinactivated effector T lymphocytes (PET cells)

Induction of tolerance for skin allotransplantation requires selective suppression of the host response to foreign histocompatibility antigens. This report describes a new approach which employs pre-treatment with 8-methoxypsoralen (8-MOP) and ultraviolet A light (UVA) to render the effector cells of graft rejection immunogenic for the syngeneic recipient. Eight days after BALB/c mice received CBA/j skin grafts, their splenocytes were treated with 100 ng/ml 8-MOP and 1 J/cm2 UVA prior to reinfusion into naive BALB/c recipients. Recipient mice were tested for tolerance to alloantigens in mixed leukocyte culture (MLC), cytotoxicity (CTL), delayed-type hypersensitivity assays (DTH), and challenge with a fresh CBA/j graft. Splenocytes from BALB/c recipients of photoinactivated splenocytes containing the effector cells of CBA/j alloantigen rejection proliferated poorly in MLC and generated lower cytotoxic T-cell responses to CBA/j alloantigens in comparison with sensitized and naive controls and suppressed the MLC and CTL response to alloantigen from sensitized and naive BALB/c mice. In vivo, the DTH response was specifically suppressed to the relevant alloantigen in comparison with controls. BALB/c mice treated in this fashion retained a CBA/j skin graft for up to 42 days post-transplantation without visual evidence of rejection. These results showed that reinfusion of photoinactivated effector cells resulted in an immunosuppressive host response which specifically inhibited in vitro and in vivo responses that correlate with allograft rejection and permitted prolonged retention of histoincompatible skin grafts.     

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.     

Evidence for a B lymphocyte defect underlying the anti-X anti-erythrocyte autoantibody response of NZB mice.

The autoimmune hemolytic anemia of NZB mice is pathogenetically mediated by a genetically prescribed anti-erythrocyte autoantibody response directed to the X erythrocyte autoantigen. The cellular locus of the immunoregulatory defect underlying the anti-X response was explored by adoptively transferring bone marrow cells (BMC) from NZB mice to lethally irradiated histocompatible recipients. Before adoptive transfer, BMC from donor mice were assayed for antigen-binding lymphocytes with receptors for the X autoantigen (X-ABL) by immunocytoadherence assays and for anti-X autoantibody-secreting cells (X-PFC) by plaque-forming cell assays. Twelve weeks after adoptive transfer, splenic lymphocytes from recipient mice were assayed for X-PFC and humoral anti-X autoantibody by Coombs' tests. Transfer of 15 to 30 x 10(6) BMC containing 6 to 12 x 10(3) X-ABL but no X-PFC from 6- to 8-week-old NZB mice to lethally irradiated BALB/c, B10.D2, C57BL/Ks, and DBA/2 mice produced X-PFC in 70% of the recipients. Development of X-PFC was not simply dependent upon available X-ABL since transfer of 15-30 x 10(6) BMC, containing comparable numbers of X-ABL, from BALB/c, B10.D2, C57BL/Ks, or DBA/2 mice to NZB or syngeneic recipients did not produce X-PFC. Transfer of BMC from NZB mice to BALB/c, B10.D2, and DBA/2 mice with weekly administrations of AKR anti-theta antiserum had no effect on the development of X-PFC; Tlymphocyte ablation was evidenced by the absence of theta+ spleen cells. These results suggest that the pathogenetic anti-X response is not genetically prescribed at the level of macrophages, humoral factors, or T cells, but rather appears to be a phenotypic expression of a primary B lymphocyte defect permitting or promoting differentiation of NZB X-ABL.     

Human CD4+ T cells mediate rejection of porcine xenografts

It has previously been demonstrated that xenograft rejection in rodents is dependent on CD4+ T cells. However, because of the lack of an appropriate in vivo model, little is known about the cellular basis of human T cell-mediated rejection of xenografts. In this study, we have evaluated the ability of human T cells to mediate rejection of porcine skin grafts in a novel in vivo experimental system using immunodeficient mice as recipients. Recombinase-activating gene-1-deficient mice (R-) lacking mature B and T cells were grafted with porcine skin and received human lymphocytes stimulated in vitro with irradiated porcine PBMC. Skin grafts on mice given either unseparated, activated human lymphocytes, or NK cell-depleted lymphocyte populations were rejected within 18 days after adoptive cell transfer. In contrast, skin grafts on mice given T cell-depleted human lymphocytes or saline showed no gross or histologic evidence of rejection up to 100 days after adoptive transfer. Purified CD4+ T cells were also able to mediate rejection of porcine skin grafts. These data suggest that human CD4+ T cells are sufficient to induce rejection of porcine xenografts. Thus, strategies directed toward CD4+ T cells may effectively prevent cellular rejection of porcine xenografts in humans.     

A novel cell type responsible for marrow graft rejection in mice. T cells with NK phenotype cause acute rejection of marrow grafts

Acute rejection of allogeneic and semiallogeneic marrow grafts has long been considered to be a function of the natural immune system because it shares many features with NK activity in mice. With the use of a recently developed in vivo adoptive transfer assay in which spleen cells are transferred from mice able to reject a particular marrow graft into mice that fail to do so, we show that the cells responsible for induction of marrow graft rejection indeed display the phenotype of NK cells: they lack the T cell Ag CD4 and CD8 but express the NK Ag NK1 and ASGM1. The rejection induced by adoptively transferred cells is exquisitely specific--a feature that points to a specific recognition process by the transferred cells. To elucidate what the recognition structure on these cells may be we found that they express CD3 and most likely the beta-chain of the TCR. Highly purified responder cells with the NK1+, CD3+, CD4-, CD8- phenotype, when transferred into nonresponder recipients, cause specific marrow graft rejection. We conclude that the acute rejection of bone marrow grafts is caused by a cell that expresses NK phenotype but is of T cell lineage. This may suggest the specificity of acute marrow graft rejection is caused by a specific recognition process that involves TCR.