ARF inhibits the growth and malignant progression of non-small-cell lung carcinoma.

Non-small-cell lung carcinoma (NSCLC) is among the deadliest of human cancers. The CDKN2A locus, which houses the INK4a and ARF tumor suppressor genes, is frequently altered in NSCLC. However, the specific role of ARF in pulmonary tumorigenesis remains unclear. KRAS and other oncogenes induce the expression of ARF, thus stabilizing p53 activity and arresting cell proliferation. To address the role of ARF in Kras-driven NSCLC, we compared the susceptibility of NIH/Ola strain wild-type and Arf-knockout mice to urethane-induced lung carcinogenesis. Lung tumor size, malignancy and associated morbidity were significantly increased in Arf(-/-) compared with Arf(+/+) animals at 25 weeks after induction. Pulmonary tumors from Arf-knockout mice exhibited increased cell proliferation and DNA damage compared with wild-type mice. A subgroup of tumors in Arf(-/-) animals presented as dedifferentiated and metastatic, with many characteristics of pulmonary sarcomatoid carcinoma, a neoplasm previously undocumented in mouse models. Our finding of a role for ARF in NSCLC is consistent with the observation that benign adenomas from Arf(+/+) mice robustly expressed ARF, while ARF expression was markedly reduced in malignant adenocarcinomas. ARF expression also frequently colocalized with the expression of p21(CIP1), a transcriptional target of p53, arguing that ARF induces the p53 checkpoint to arrest cell proliferation in vivo. Taken together, these findings demonstrate that induction of ARF is an early response in lung tumorigenesis that mounts a strong barrier against tumor growth and malignant progression.

Inhibition of PI-3K restores nuclear p27Kip1 expression in a mouse model of Kras-driven lung cancer.

Reduced expression of the CDK inhibitor p27(Kip1) (p27) in human lung cancer correlates with tumor aggressiveness and poor prognosis. However, the regulation of p27 expression and the role of p27 during lung cancer are poorly understood. Urethane-induced lung tumors in mice frequently harbor mutations in the Kras oncogene, and in this study, we use this model to address the regulation of p27 during tumorigenesis. The Ras effector Akt is known to regulate p27 mRNA abundance by phosphorylating and inactivating the FOXO transcription factors. Phosphorylated Akt and FOXO proteins were both increased in lung tumors, correlating with a reduction in p27 mRNA transcript. Akt also directly phosphorylates p27 and regulates its nuclear/cytoplasmic localization. Tumors showed a reduced nuclear/cytoplasmic ratio of p27 protein, together with an increase in phosphorylated Thr197 p27 in the cytoplasmic pool. Treatment of lung tumor-bearing mice with the phosphoinositol-3 kinase inhibitor LY294002 induced a rapid decrease in phosphorylated Akt and phosphorylated p27, concomitant with an increase in nuclear p27. Germline p27 deficiency accelerated both the growth and malignant progression of urethane-induced lung tumors, and did so in a cell autonomous manner, confirming a causal role of p27 in tumor suppression. These results show that p27 is a potent barrier to the growth and malignant progression of Kras-initiated lung tumors. Further, the reduction of nuclear p27 in tumors is mediated by oncogene signaling pathways, which can be reversed by pharmacological agents.

Synthetic lethality between mutation in Atm and DNA-PK(cs) during murine embryogenesis.

The gene product mutated in ataxia telangiectasia, ATM, is a ubiquitously expressed 370 kDa protein kinase that is a key mediator of the cellular response to DNA damage [1]. ATM-deficient cells are radiosensitive and show impaired cell cycle arrest and increased chromosome breaks in response to ionizing radiation. ATM is a member of the phosphatidylinositol-3-kinase (PI3K)-related protein kinase superfamily, which includes the catalytic subunit of DNA-dependent protein kinase (DNA-PK(cs)) and ATR [2]. DNA-PK is a 470 kDa protein kinase that is required for proper end-to-end rejoining of DNA double-strand breaks [3]. Prkdc(scid/scid) mice have a homozygous mutation in the gene encoding DNA-PK(cs) and, like Atm(-/-) mice, are viable and radiosensitive [4-8]. To determine if Atm and DNA-PK(cs) show genetic interaction, we attempted to generate mice deficient in both gene products. However, no scid/scid Atm(-/-) pups were recovered from scid/scid Atm(+/-) intercrosses. Developmental arrest of scid/scid Atm(-/-) embryos occurred around E7.5, a developmental stage when embryonic cells are hypersensitive to DNA damage [9]. This reveals synthetic lethality between mutations in Atm and DNA-PK and suggests that Atm and DNA-PK have complementary functions that are essential for development.

p53 induction and apoptosis in response to radio- and chemotherapy in vivo is tumor-type-dependent.

The p53 protein rapidly accumulates in cells in response to DNA damage, which can trigger apoptosis. This pathway is hypothesized to be important for tumor suppression by p53, as well as for the response of tumors to chemo- or radiotherapy. Implicit in these ideas is that the p53 induction-apoptosis pathway is active in tumor cells in vivo. Because tumor suppression by p53 in mice is markedly tissue-type-dependent, we tested the activity of the pathway in tumors in vivo by inducing tumors in six different tissues and treating tumor-bearing mice with DNA damaging cancer therapeutic agents. In response to treatment, cells from T-cell lymphomas, intestinal adenomas, and mammary tumors rapidly induced p53 and underwent apoptosis. In squamous cell papillomas, p53 was constitutively expressed and was further induced by the treatments, but apoptotic cells were only rarely observed. In treated mice bearing lung or liver adenomas, minimal or no p53 accumulation or apoptosis was observed in the tumor cells. Thus, there is marked variation in the intrinsic ability of autochthonous tumor cells to accumulate p53 and undergo apoptosis. This variation provides one explanation for the tissue specificity of tumor suppression by p53. It also indicates that the role of apoptosis in the response of tumors to therapy varies significantly among tumor types.

Resistance to skin tumorigenesis in DNAPK-deficient SCID mice is not due to immunodeficiency but results from hypersensitivity to TPA-induced apoptosis.

Scid/scid mice have a mutation in the gene encoding the catalytic subunit of DNA-dependent protein kinase (DNAPK(cs)) and are defective in end joining of DNA double-strand breaks. As a consequence, they are radiosensitive, lack mature T and B lymphocytes and are predisposed to lymphomagenesis. To determine if this DNA repair defect also increased predisposition to skin tumor formation, we treated the dorsal skin of scid/scid mice with the carcinogen 7,12-dimethylbenz[a]anthracene followed by the tumor promoter 12-O-tetradecanoylphorbol-13-acetate (TPA). Contrary to expectations, we observed a 5-fold reduction in skin tumor multiplicity in scid/scid mice. We addressed whether this was related to their immunodeficiency by similarly treating Rag1(-/-) and Rag2(-/-) knockout mice which also lack mature T and B lymphocytes. We observed no difference in skin tumor multiplicity for either strain compared with control littermates. This indicates a lack of a significant role for T or B lymphocyte mediated immunity on either papilloma or carcinoma formation. We observed a significant increase in apoptotic and necrotic cell death in follicular and interfollicular epithelial cells of scid/scid mice following TPA treatment. This hypersensitivity of SCID (severe combined immunodeficient) cells to TPA indicates that the resistance to skin tumor formation in scid/scid mice is due to loss of initiated cells through TPA-induced cell killing.

Tumor suppression by p27Kip1 and p21Cip1 during chemically induced skin carcinogenesis.

p27Kip1 and p21Cip1 are cyclin dependent kinase inhibitors which can arrest cell proliferation and p27 is a tumor suppressor gene. To address the mechanism of tumor suppression by p27 and to determine if p21 has a tumor suppressor phenotype, we utilized the two stage skin carcinogenesis model on p27 and p21 knockout mice. In this model, initiation, which involves mutation of H-ras induced by DMBA, can be distinguished from promotion induced by TPA, and progression to carcinoma. The mean number of papillomas did not differ between p27-/- and control littermates, but papilloma growth rate was increased and carcinomas developed earlier. Thus, p27 deficiency did not enhance initiation, but resulted in more rapid clonal expansion of initiated cells during promotion. TPA treatment reduced p27 expression in keratinocytes also supporting a role for p27 during promotion. Tumors from p27-/- mice contained mutant H-ras indicating that p27 deficiency did not substitute for mutant ras and further, that during ras driven tumor growth, p27 is partially antagonistic since its removal led to faster growth. The treated p27-/- mice also developed intestinal adenomas. p21-/- mice did not display a significant increase in tumor numbers, growth rate or progression to carcinomas and these tumors also had mutated H-ras. Carcinomas from p21-/- mice were more poorly differentiated with a high frequency of anaplastic spindle cell carcinomas. Thus p21 deficiency mainly resulted in higher grade undifferentiated tumors.

The murine gene p27Kip1 is haplo-insufficient for tumour suppression.

p27Kip is a candidate human tumour-suppressor protein, because it is able to inhibit cyclin-dependent kinases and block cell proliferation. Abnormally low levels of the p27 protein are frequently found in human carcinomas, and these low levels correlate directly with both histological aggressiveness and patient mortality. However, it has not been possible to establish a causal link between p27 and tumour suppression, because only rare instances of homozygous inactivating mutations of the p27 gene have been found in human tumours. Thus, p27Kip1 does not fulfil Knudson's 'two-mutation' criterion for a tumour-suppressor gene. Here we show that both p27 nullizygous and p27 heterozygous mice are predisposed to tumours in multiple tissues when challenged with gamma-irradiation or a chemical carcinogen. Therefore p27 is a multiple-tissue tumour suppressor in mice. Molecular analyses of tumours in p27 heterozygous mice show that the remaining wild-type allele is neither mutated nor silenced. Hence, p27 is haplo-insufficient for tumour suppression. The assumption that null mutations in tumour-suppressor genes are recessive excludes those genes that exhibit haplo-insufficiency.

DNA double-strand breaks, p53, and apoptosis during lymphomagenesis in scid/scid mice.

The tumor-suppressing phenotype of p53 is thought to be due to its accumulation in response to DNA damage and resultant cell cycle arrest or apoptosis. scid/scid mice are defective in DNA double-strand break repair due to a mutation in DNA-dependent protein kinase (DNAPK). Treatment of scid/scid mice with gamma radiation or N-ethyl-N-nitrosourea resulted in approximately 86% incidence of T-cell lymphomas, compared with <6% in wild-type mice. The incidence of other tumor types was not increased in scid/scid mice, suggesting that the types of DNA double-strand break that are unrepaired in these mice are not strongly carcinogenic. To determine whether mutations in DNAPK and p53 interact, we examined mice deficient in both genes. Both scid/scid p53-/- and scid/scid p53+/- mice spontaneously developed lymphomas at shorter latency than did mice with either defect alone. Loss of the wild-type p53 allele was observed in 100% of tumors from scid/scid p53 +/- mice, indicating strong selection against p53. In contrast, p53 was not inactivated in lymphomas from scid/scid p53+/+ mice. Exposure of these tumor-bearing mice to gamma radiation resulted in p53 protein accumulation and high levels of apoptosis in all tumors that were not observed in tumors from scid/scid p53+/- mice. Thus, there was a bifurcation of molecular pathways to tumorigenesis. When p53 was heterozygous in the germ line, loss of the wild-type allele occurred, and the tumors became apoptosis resistant. When p53 was wild type in the germ line, p53 was not inactivated, and the tumors remained highly apoptosis sensitive.

p53 induction, cell cycle checkpoints, and apoptosis in DNAPK-deficient scid mice.

The p53 tumor suppressor protein is rapidly induced following treatment of cells with agents which cause DNA double strand breaks (dsbs) leading to cell cycle arrest and/or apoptosis. Scid mutant mice are defective in repair of DNA dsbs which was recently shown to be due to lack of DNA-dependent protein kinase (DNAPK) activity. DNAPK is normally activated by DNA dsbs and phosphorylates the p53 protein. Here we tested the hypothesis that DNAPK transduces the signal from DNA dsbs to p53 induction. P53 protein was properly induced in intestinal crypt cells of irradiated scid mice and was functional as detected by the large increase in apoptotic cells. P53 induction was prolonged, consistent with DNA dsbs as the signal to induce p53. Spontaneous levels of apoptosis were elevated suggesting that scid mice are sensitive indicators of spontaneously generated DNA dsbs. Primary scid fibroblasts underwent normal G1 and G2 arrest in response to doxorubicin. DNAPK is not required for p53 induction, cell cycle arrest, or apoptosis after DNA damage.

Induction of tolerance to heart allografts in rats using posttransplant total lymphoid irradiation and anti-T cell antibodies.

This study examined whether posttransplant anti-T cell monoclonal or polyclonal antibody therapy could provide a window of treatment to allow posttransplant total lymphoid irradiation (TLI) to induce tolerance. These experiments were conducted in a high responder strain combination of an ACI cardiac allograft into a Lewis rat. In this situation, treatment with antibody or posttransplant TLI alone is insufficient to induce tolerance, while similar treatments alone have been shown to induce tolerance in low responder strains. The affects of three anti-T cell therapies were compared: anti-CD4 mAb therapy, anti-CD3 mAb, and rabbit antithymocyte globulin (RATG). None of these antibody therapies alone prolonged graft survival indefinitely. Combining anti-CD4 therapy with posttransplant TLI markedly delayed rejection but failed to induce long-term graft survival. Tolerance could be induced by a combination of anti-pan T cell antibody (anti-CD3) and TLI, and, all grafts survived beyond 100 days. RATG failed to prevent graft rejection when used alone or in combination with TLI. However, posttransplant therapy with a combination of RATG, TLI, and single-donor blood transfusion resulted in graft survival beyond 100 days. Recipients bearing long-term donor grafts rejected third-party (PVG) grafts within 2 weeks. Low density donor bone marrow cells used instead of a blood transfusion did not facilitate tolerance. The results indicate that monoclonal or polyclonal anti-pan T cell antibodies, TLI, and a donor blood cell infusion function synergistically in facilitating tolerance to allografts in the posttransplant period.

Induction of long-term specific tolerance to allografts in rats by therapy with an anti-CD3-like monoclonal antibody.

Monoclonal antibodies to CD3 have been shown to activate T cells in vivo and in vitro but have also been shown to render T cells anergic in vitro. In this study G4.18, a mouse IgG3 mAb, was produced that appeared to recognize CD3 by its binding to all peripheral T cells, including a population not recognized by mAb to TCR-alpha/beta that was presumed to be TCR-gamma/delta cells. It precipitated molecules in the 24-26 kd region consistent with the CD3 complex as well as molecules approximately 45 and approximately 49 kd that corresponded to TCR alpha and beta chains and a 92-kd complex. Incubating T cells for 24 hr with saturating concentrations of G4.18 caused modulation of the TCR complex. In vitro, it activated T cells but only if prebound to plastic. In solution it inhibited MLC and CML, but not PHA or Con A activation. In vivo, G4.18 was not toxic even in high doses, and this was thought to be due to the inability of this mAb to activate T cells in vitro because the rat lacks Fc receptors for mouse IgG3. Therapy with G4.18 resulted in transient modulation of TCR/CD3 on T cells and depletion of these cells from blood. G4.18 had no depleting effects by lymph node or spleen cells but caused marked, transient thymic involution. Therapy with G4.18 also induced indefinite survival (> 100 days) of PVG (RTIc) heart grafts but not skin grafts in DA (RTIa) hosts. These hosts with long-surviving cardiac transplants, when grafted from PVG skin, accepted these grafts but rejected third-party skin in first-set. Thus G4.18 was shown to induce long-term specific tolerance to an organ allograft.

Specific unresponsiveness in rats with prolonged cardiac allograft survival after treatment with cyclosporine. V. Dependence of CD4+ suppressor cells on the presence of alloantigen and cytokines, including interleukin 2.

CD4+ cells from CsA-treated DA rats with long-surviving PVG heart allografts specifically suppress the capacity of naive CD4+ cells to restore allograft rejection in irradiated DA rats, but have normal donor-specific alloreactivity in MLC. CD4+ suppressor cells from CsA-treated DA rats cultured for 3 days against either PVG or DA spleen cells lost the capacity to transfer suppression into irradiated DA rats grafted with PVG hearts and regained the ability to mediate rejection. However, these cells retained suppressor function when stimulated with donor-specific alloantigen in media supplemented with 20% Con A supernatant. CD4+ cells from CsA-treated rats cultured against either third-party stimulator cells or syngeneic cells expressing anti-PVG idiotype in media supplemented with Con A supernatant failed to maintain suppressor cell function. CD4+ cells from CsA-treated rats cultured in media supplemented with Con A supernatant alone also failed to maintain suppressor function. Suppressor cell function in culture was not maintained by rIL-2. mAb to the IL-2 receptor alpha chain (CD25) prevented the maintenance of suppressor cell function in media supplemented with Con A supernatant. Con A supernatant is rich in IFN-gamma, but addition of an anti-IFN-gamma mAb to the culture did not affect the maintenance of suppressor cells. These studies demonstrate that the CD4+ suppressor cell from CsA-treated rats with long-surviving grafts is short-lived; its survival is dependent upon contact with specific alloantigens and cytokines, one of which is IL-2. In the absence of cytokines and/or specific alloantigen, the CD4+ cells regain the capacity to initiate graft rejection in irradiated rats, suggesting that within the CD4+ subpopulation there is a fragile balance between cells with the capacity to suppress and effect rejection.

Specific unresponsiveness in rats with prolonged cardiac allograft survival after treatment with cyclosporine. VI. In vitro alloreactivity of T cell subsets from rats with long-surviving allografts.

DA rats treated with a short course of cyclosporine develop specific unresponsiveness to RT1-incompatible PVG donor heart allografts. CD4+ cells, not CD8+ cells, transfer unresponsiveness to irradiated rats. However, host-derived CD8+ cells are important in reestablishing unresponsiveness. In this study, unfractionated lymphoid cells and W3/25+ (CD4+) cells from CsA-treated rats with long-surviving PVG allografts demonstrated normal alloreactivity to PVG alloantigen in the mixed lymphocyte culture and failed to suppress the proliferative response of naive W3/25+ cells to donor-specific alloantigen. MRC OX8+ (CD8+) cells did not proliferate. Sera from CsA-treated rats had no effect on the MLC reactivity of cells from CsA-treated rats, suggesting that blocking or antiidiotypic antibodies did not diminish alloreactivity. IL-2 production by W3/25+ cells from CsA-treated rats was similar to that by W3/25+ cells from naive rats. Specific cytotoxic T cells to PVG were generated in MLC, and the frequency of precursor cytotoxic lymphocytes in CsA-treated rats was similar to that in naive DA rats. In an in vitro assay testing response to idiotype, neither W3/25+ or MRC OX8+ cells from unresponsive rats proliferated. As CD4+ cells from CsA-treated rats lose their capacity to adoptively transfer specific unresponsiveness unless maintained in a cytokine-rich supernatant, all in vitro assays were performed with and without added cytokines, but no change in reactivity consistent with suppression was observed in any assay. CD4+ suppressor cells had no effect on conventional in vitro assays of alloreactivity, preventing the detection of the unresponsiveness in vitro.

Specific unresponsiveness in rats with prolonged cardiac allograft survival after treatment with cyclosporine. III. Further characterization of the CD4+ suppressor cell and its mechanisms of action.

The cellular basis of the specific unresponsiveness that develops in DA rats treated with cyclosporine (CSA) for 10 d after grafting a PVG heart was examined using an adoptive transfer assay. CD4+ cells from rats with long survival grafts specifically lack the capacity to restore PVG heart graft rejection, and can also inhibit the capacity of naive T cells to restore rejection, while in the first few weeks post-transplant, both CD4+ and CD8+ T cells from CSA-treated hosts have the capacity to effect PVG graft rejection. In this study, we demonstrated the CD4+ suppressor cells also had the capacity to inhibit restoration of rejection by CD4+ cells from CSA-treated DA rats recently transplanted with PVG hearts, and from rats sensitized to third party, but not from those specifically sensitized to PVG. They also inhibited the capacity of both naive CD8+ and sensitized CD8+ cells to effect rejection. These results showed that the CD4+ suppressor cell was capable of overriding the capacity to effect rejection of the CD4+ cell and activated CD8+ cells that were present in the CSA-treated host shortly after transplantation. The failure of naive CD8+ cells to augment suppression and the capacity of CD4+ suppressor cells to transfer unresponsiveness to irradiated hosts in which regeneration of CD8+ cells was abolished by thymectomy suggested that it was the CD4+ cell alone that mediated suppression. However, the failure of CD4+ suppressor cells to reinduce unresponsiveness in irradiated hosts whose CD8+ cells had been depleted by therapy with the mAb MRC Ox8 showed that a radioresistant CD8+ cell was required to reestablish the state of specific unresponsiveness. The induction of CD4+ suppressor cells in thymectomized hosts suggested that these cells were derived from long-lived CD4+ lymphocytes. However, their sensitivity to cyclophosphamide and their loss of suppressor function both after removal of the graft and after 3 d in culture demonstrated that the suppressor cell itself had a short lifespan. The CD4+ suppressor was shown to be MRC Ox22+ (CD45R+), MRC Ox17+ (MHC class II), and MRC Ox39+ (CD25, IL-2-R). These studies demonstrated the CD4+ suppressive cell identified in rats with specific unresponsiveness induced by CSA therapy had many features of the suppressor inducer cell identified in in vitro studies of the alloimmune response.(ABSTRACT TRUNCATED AT 400 WORDS)

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.

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.

Specific unresponsiveness in rats with prolonged cardiac allograft survival after treatment with cyclosporine. II. Sequential changes in alloreactivity of T cell subsets.

A 10-day course of cyclosporine treatment inhibits the capacity of DA rats to reject PVG heart grafts and leads to the development of specific unresponsiveness and indefinite graft survival, which is mediated by a W3/25+ (CD4+) suppressor cell. In this study the sequential changes in the alloreactivity of the CD4+ and CD8+ subsets of CsA-treated DA rats were examined. During the induction phase, 8 and 20 days posttransplant, W3/25+ cells retained normal alloreactivity in that they adoptively restored PVG heart graft rejection in irradiated DA rats. By day 50 they had lost their capacity to restore rejection of PVG grafts but still retained their capacity to effect third party W/F graft rejection. W3/25+ cells from control grafted rats adoptively restored PVG graft rejection even at 75 days posttransplant, suggesting that the loss of alloreactivity of W3/25+ cells in CsA-treated rats was due to the prevention of rejection by CsA, and not a consequence of sensitization to alloantigen. MRCOX8+ cells from CsA-treated rats showed some evidence of sensitization at days 8 and 20 but lost this by day 50. These studies showed that during the induction phase, normal alloreactivity of W3/25+ cells is retained and sensitization of MRCOX8+ cells occurs. Specific loss of reactivity and suppressor potential of W3/25+ cells developed later, when specific unresponsiveness to second donor strain grafts developed in these hosts.