DNA associated with the cell membrane is involved in the inhibition of the skin rejection response induced by infusions of photodamaged alloreactive cells that mediate rejection of skin allograft.

Cell membrane DNA (cmDNA) is a form of DNA located on the surface of human and murine T-cells. It has recently been characterized as a target for photomodification by 8-methoxypsoralen (8-MOP) and long-wave ultraviolet light (UV-A). Whereas 8-MOP itself is biologically inert, photoactivated 8-MOP is covalently bound to pyrimidine bases in DNA. We have investigated the possible involvement of cmDNA photomodification in the induction of the suppression of skin allograft rejection in BALB/c mice preimmunized with 8-MOP/UV-A photodamaged alloreactive cells which mediates this allograft rejection. This suppression is demonstrated by inhibition of delayed-type hypersensitivity (DTH) and mixed leukocyte culture (MLC) responses. Splenocytes from BALB/c mice undergoing rejection of CBA/j skin graft which contained an expanded population of the effector T lymphocytes that mediate the rejection were treated with DNAse to remove cmDNA before or after treatment with 8-MOP and UV-A prior to infusion into naive BALB/c recipients. Mice that received pretreated effector cells were tested for MLC responses to CBA/j or B10 alloantigens before and after the DTH response. The DTH response of all groups of pretreated BALB/c mice to the relevant alloantigen was specifically suppressed as compared with the response of control mice. However, adoptive transfer of the suppression of the DTH response was optimally demonstrable only in syngeneic recipients of cells from donor mice treated with photodamaged alloreactive cells. Also, splenocytes from BALB/c mice immunized with photodamaged alloreactive cells demonstrated highly significant hyporesponsiveness and suppression of the MLC response of naive mice to the relevant alloantigen in the case of the primary MLC response, and to both alloantigens in the secondary MLC response which was totally eliminated by prior pretreatment of these effector cells with DNAse. Therefore, it appears that the suppression of the DTH response can be induced by pretreatment of the effector cells with DNAse and/or 8-MOP and UV-A but is adoptively transferable optimally only from mice which are recipients of photodamaged alloreactive cells. Moreover, the effectiveness of this treatment is decreased by prior removal of cmDNA from these cells. The presence of cmDNA is necessary for induction of suppression of the primary and secondary MLC responses in mice treated with photodamaged cells of allograft rejection.

[Whole body irradiation]. / L'irradiation corporelle totale.

Total body irradiation produces a sufficient immunosuppression to prevent an allograft rejection. It can be used with chemotherapy as an "intensive" treatment aiming at the complete eradication of a malignancy--with the resulting bone marrow aplasia needing an autologous or allogeneic transplantation. In either case, a dose of some 10 Gy has to be delivered in the whole body, in one session at low dose rate or fractionated between several sessions. Such a dose is usually well tolerated--at any rate it does not carry too high a risk to contribute to induce an interstitial pneumonitis or a venous occlusive disease of the liver. The antitumoral efficacy of such limited dose is mainly important against very radiosensitive tumours--first of all leukemias and lymphomas. Yet some groups use also total body irradiation in the treatment of some solid tumours of dismal prognosis--for instance in case of advanced neuroblastomas or Ewing's sarcomas.

Cis-urocanic acid as a mediator of ultraviolet-light-induced immunosuppression.

Treatment of an organism with UVB light or PUVA (8-methoxypsoralen + UVA light) not only leads to alterations in the irradiated skin but also to systemic immunomodulation, due to the release of several chemical mediators of immunosuppression like prostaglandins, acute-phase proteins, IL-1 inhibitor, alpha-melanocyte-stimulating hormone, propiomelanocorticotropin or other cytokines. A recently described mediator is urocanic acid, which is transformed by UV light in the skin from the trans- to the cis-isomer and that exerts a systemic immunomodulatory effect. In our experiments, treatment with PUVA or with cis-urocanic acid prevents the rejection of rat heart allografts in 50% and 40% of cases, respectively. Control grafts are rejected in fewer than 10 days. PUVA treatment of donor leukocytes before transfusion into the prospective recipient inhibits only their sensitizing, not their graft-protecting, effect on subsequent skin grafts in mice. PUVA treatment also prevents acute lethal GVH disease in mice after irradiation with a sublethal dose of x-rays and transfusion of semiallogeneic spleen cells. Treatment of recipient mice with cis-urocanic acid has the same effect. The humoral immune response to sheep erythrocytes is not influenced by cis-urocanic acid. These results demonstrate that PUVA treatment or its chemical mediator, cis-urocanic acid, may be used in transplantation and hematology as naturally occurring immunosuppressive agents, especially for the control and manipulation of GVH leukemia reaction.

Photoinactivation of lymphohemopoietic cells: studies in transfusion medicine and bone marrow transplantation.

Ultraviolet (UV) irradiation affects eukaryotic cells in numerous ways. Exposure of blood transfusion products to UVC (200-280 nm) or UVB (280-320 nm) reduces or abrogates their immunogenicity and thereby prevents allosensitization and transfusion refractoriness in several models. Although the exact mechanism is not known, in vitro studies suggest that UV exposure results in a loss of class II histocompatibility antigens from the cell surface, alterations of calcium homeostasis, and a lack of interaction between antigen presenting and responding cells. In the UVB and UVA (320-400 nm) range, lymphocytes appear to be more sensitive than hemopoietic cells. In murine transplant models, UVB irradiation of spleen and marrow cells can be used to prevent the development of graft-versus-host disease while allowing for complete hemopoietic reconstitution. Furthermore, in clinical marrow transplantation, pilot studies of UVA in conjunction with psoralen administration have yielded encouraging results in patients with steroid refractory graft-versus-host disease of the skin. Thus, UV irradiation provides an interesting tool to study cell/cell and donor/host interactions and may have some applications in transfusion medicine and bone marrow transplantation.

Late failure of autologous marrow grafts in lethally irradiated dogs given anti-class II monoclonal antibody.

We established a model of canine marrow autografts after 9.2 Gy total body irradiation (TBI) to study the role of class II antigens in hematopoietic stem cell growth and differentiation. Twenty dogs were given 9.2 Gy TBI, marrow, and intravenous (IV) murine anti-class II monoclonal antibody (MoAb). Infusion of 0.6 mg/kg/d of MoAb H81.98.21, an IgG2a reactive with HLA-DR, on days 0 to 4 after TBI did not prevent initial engraftment, but dogs died with late graft failure. MoAb B1F6, an IgG2a reactive with HLA-DR + DP, had no adverse effect on engraftment, although both MoAbs detect antigens on stem cells. The critical time for the effect of MoAbs is the first 4 days after transplantation. Our findings argue against several pathogenetic mechanisms, including removal of MoAb-coated stem cells by the reticuloendothelial system (RES), canine complement-mediated cytotoxic effects on stem cells, antibody-dependent cellular cytotoxicity, and inactivation of MoAb-coated cells by dog anti-mouse antibody. To distinguish between MoAb-induced damage to microenvironment (ME)/accessory cells (AC) and late graft failure from a lack of pluripotent stem cells, three dogs were given TBI, a marrow autograft, and MoAb H81.98.21 on days 0 to 4; one, given thoracic duct cells on day 6, developed graft failure; the other two, given marrow depleted of AC by L-leucyl L-leucine o-methyl ester (Leu-Leu-OMe), had sustained grafts. Findings support the notion that originally transplanted pluripotent stem cells are no longer present on day 6 and that the ME is functional and able to support newly injected stem cells.

Total lymphoid irradiation and total body irradiation for allogeneic bone marrow transplantation in aplastic anemia.

Between April 1980 and June 1989, 15 patients with severe aplastic anemia (SAA) were treated at Hyogo College of Medicine with bone marrow transplantation (BMT) after preparation consisting of cyclophosphamide (CY) and total lymphoid irradiation (TLI) or total body irradiation (TBI) for the purpose of reducing the incidence of graft rejection. All patients had initial evidence of engraftment after the first transplantation except for one patient who died of heart failure due to CY on the third day after transplantation and could not be evaluated for engraftment. Rejection later occurred in four of these 14 patients, who then underwent successful regrafting. One of these patients, who was conditioned with CY alone at the first grafting, underwent successful regrafting after a conditioning regimen of CY and TBI. In the other three patients, irradiation was performed twice as the conditioning regimen. Thus, 14 of 15 patients underwent successful BMT and are alive with restored hematopoietic function. From the above results, the combination of TLI or TBI and CY was considered to be very useful as a conditioning regimen for BMT in patients with SAA.

Total orthotopic allogeneic small bowel transplantation in rats: effect of allograft irradiation combined with cyclosporine-A therapy.

Rejection and graft versus host disease are prominent features in small bowel allotransplantation in rats. Cyclosporine treatment of the recipient and irradiation of the donor were used to circumvent these phenomena in the WAG to brown Norway rat model. Irradiation of the donor with five or 10 Gy did prevent graft versus host disease but resulted in a more vigorous rejection of small bowel allografts in untreated recipients (mean (SEM) survival times of 11.5 (0.4) (n = 8) and 7.5 (0.9) (n = 11) days respectively, versus 16.6 (2.6) days (n = 17), p less than 0.01). Cyclosporine treatment of the recipient (25 mg/kg on days 0, 1, 2, 4, and 6 after transplantation) led to a mean (SEM) survival time of 38.3 (8.5) days (n = 10); 20% of the animals developed graft versus host disease. Combined with 5 Gy donor pretreatment, a similar survival was obtained without occurrence of graft versus host disease. However, cyclosporine treatment combined with 10 Gy led to a significant shortening of graft survival (23.1 (6.8) days, n = 9). These results suggest that although irradiation is very effective in preventing graft versus host disease, high dosages may accelerate rejection either by making the graft more vulnerable to rejection or by completely removing the immuno-suppressive effect of graft versus host disease.

Total lymphoid irradiation for treatment of intractable cardiac allograft rejection.

The ability of postoperative total lymphoid irradiation to reverse otherwise intractable cardiac allograft rejection was examined in a group of 10 patients in whom conventional rejection therapy (including pulsed steroids and monoclonal or polyclonal anti-T-cell antibody therapy) had failed to provide sustained freedom from rejection. Follow-up periods range from 73 to 1119 days since the start of total lymphoid irradiation. No patient died or sustained serious morbidity because of the irradiation. Three patients have had no further rejection (follow-up periods, 105 to 365 days). Two patients died--one in cardiogenic shock during the course of total lymphoid irradiation, the other with recurrent rejection caused by noncompliance with his medical regimen. Total lymphoid irradiation appears to be a safe and a moderately effective immunosuppressive modality for "salvage" therapy of cardiac allograft rejection unresponsive to conventional therapy.

Total lymphoid irradiation to prevent graft rejection in recipients of HLA non-identical T cell-depleted allogeneic marrow.

Patients who undergo transplantation with genotypically non-identical T cell-depleted bone marrow are at high risk of graft failure. We have previously shown that graft failure in this setting is an active immunologic process in which CD3+ CD8+ host T cells specifically cytotoxic for donor hematopoietic cells mediate rejection of the graft. In order to reduce the incidence of graft rejection in these patients, we conducted a pilot trial of total lymphoid irradiation (TLI) as an adjunct to total body irradiation (TBI) in an attempt to suppress the activity of residual host derived alloreactive lymphocytes capable of mediating rejection. Ten adults (ages 17-42 years) with hematologic malignancies were treated with TLI prior to hospitalization for allogeneic bone marrow transplantation (BMT). The BMT preparative regimen consisted of cyclophosphamide (60 mg/kg x 2) followed by TBI. The majority of patients received 750 cGy TLI delivered to two complementary radiation ports in five equal 150 cGy fractions. Nine of 10 recipients of genotypically non-identical CD6-depleted marrow who were pre-treated with TLI experienced full hematologic engraftment compared with none of four similar patients previously transplanted without TLI (p = 0.001). TLI induced significant lymphopenia in patients prior to marrow infusion, but had no suppressive effects on the reconstitution of donor lymphocytes. TLI, in combination with T cell depletion of donor marrow, may decrease the rate of graft rejection in individuals who lack perfectly matched HLA-identical sibling donors.

Use of yttrium-90-labeled anti-Tac antibody in primate xenograft transplantation.

The high-affinity interleukin-2 receptor (IL-2R) is expressed by T cells activated in response to foreign histocompatibility antigens but not by normal resting cells. Thus, blockade of the interaction of IL-2 with its receptor could achieve selective immunosuppression. Accordingly, anti-Tac, a murine IgG2a class monoclonal antibody specific to the IL-2R, was used alone or in a chelated form with yttrium-90 (90Y), a pure beta emitter, to inhibit rejection of cardiac xenografts from Macaca fascicularis (cynomolgus) donors transplanted to the cervical or abdominal region of Macaca mulatta (rhesus) recipients (n = 20). Animals received no immunosuppression (n = 3, group I, controls), unmodified anti-Tac (n = 5, 2 mg/kg q.o.d., group II), or 90Y-anti-Tac (n = 5, 16 mCi, group III). To distinguish the nonspecific immunosuppressive effect of radiation, 90Y was administered bound to UPC-10 (n = 4, 16 mCi, group IV), another murine monoclonal antibody that does not specifically recognize activated immunoresponsive cells. All immunosuppression was administered in divided doses during the first 2 weeks posttransplant. Group I animals rejected their grafts at 6.7 +/- 1 days and demonstrated a rise in soluble IL-2R levels at the time of rejection, indicating the generation of Tac-expressing and -releasing cells. Graft survival in group II was not prolonged compared with controls (mean survival 6.2 +/- 1 days; P greater than 0.05). In contrast, graft survival in animals that received the designed dosage of 90Y-anti-Tac was significantly prolonged to an average of 38.4 +/- 5 days compared with groups I and II (P less than 0.005 and P les sthan 0.0005, respectively). Prolongation of graft survival occurred in animals that received 90Y-UPC-10 (mean survival 21.3 +/- 5 days, P less than 0.05 versus group I, P less than 0.01 versus group II). However, 90Y-UPC-10 was significantly less effective in prolonging graft survival than 90Y-anti-Tac, in which one-half the per-kilogram dosage of radioactivity was delivered in specific fashion via anti-Tac (P less than 0.025). Reversible nonlethal bone marrow suppression occurred without associated nephro- or hepatotoxicity, and virtually all animals developed antibodies to the murine monoclonal. Thus, the approach used in the present study, IL-2R-directed therapy with 90Y-anti-Tac, may have potential applications in organ transplantation and in the treatment of Tac-expressing neoplastic diseases.

Prevention of graft rejection in allogeneic bone marrow transplantation. II. Preclinical studies with three radiation protocols.

Three radiotherapeutic regimens were compared in vitro to determine their immunosuppressive potential against non-MHC-restricted cytotoxic cells. Assays of natural killer and lymphokine-activated killer function, and cytotoxicity against allogeneic cells were used to quantitate the cytotoxic potential of peripheral blood mononuclear cells from healthy individuals following irradiation with a single dose of 1000 cGy on day 0, 1320 cGy of fractionated radiation (165 cGy b.i.d. x 4 days), or "split-dose" irradiation consisting of 1000 cGy on day 0 followed 5 or 7 days later by 500 cGy. Both irradiated and nonirradiated (control) PBMC cultures were maintained in culture with medium containing interleukin-2, immunophenotyped, and assayed for cytotoxicity from 1 to 8 days after irradiation. Single dose and fractionated-dose irradiation resulted in a progressive decline in cytotoxic capacity, with an 80% inhibition of both NK and LAK cell activity 8 days after onset of irradiation. The split dose of 500 cGy administered 7 days after a dose of 1000 cGy was found to be the most effective in eliminating NK (93% inhibition) and LAK (100% inhibition) cytotoxicity. These data indicate that split-dose irradiation may result in greater immuno-suppression than single-dose or fractionated irradiation.

Prevention of the induction of allospecific cytotoxic T lymphocyte and delayed-type hypersensitivity responses by ultraviolet irradiation of corneal allografts.

The effect of ultraviolet radiation (UVR) on the immunogenicity of corneal allografts was examined in a mouse model. Corneal allografts differing from the host at the entire MHC and multiple minor H loci were subjected to 200 mJ/cm2 of UVB irradiation immediately prior to heterotropic transplantation. Analysis of cytotoxic T lymphocyte and delayed-type hypersensitivity responses revealed that UVR treated corneal grafts failed to induce either CTL or DTH responses in C57BL/6 recipients. UVB treatment abolished the immunogenicity of highly immunogenic corneal grafts containing either resident or infiltrating donor-specific Langerhans cells. Sequential grafting experiments demonstrated that UVB-treated grafts rendered the hosts anergic to subsequent immunization with highly immunogenic corneal limbus grafts that contained dense concentrations of Ia+ Langerhans cells of donor origin. The results indicate that UV treatment not only reduces the immunogenicity of the corneal allograft but may also render it tolerogenic.

Inability of donor total body irradiation to prolong survival of vascularized bone allografts: experimental study in the rat.

At the present time, the toxic side effects of recipient immunosuppression cannot be justified for human non-vital organ transplantation. Total body irradiation has proven effective in ablating various bone-marrow-derived and endothelial immunocompetent cellular populations, which are responsible for immune rejection against donor tissues. Irradiation at a dose of 10 Gy was given to donor rats six days prior to heterotopic transplantation of vascularized bone allografts to host animals. Another group of recipient rats also received a short-term (sixth to fourteenth day after grafting), low dose of cyclosporine. Total body irradiation was able merely to delay rejection of grafts across a strong histocompatibility barrier for one to two weeks, when compared to nonirradiated allografts. The combination of donor irradiation plus cyclosporine did not delay the immune response, and the rejection score was similar to that observed for control allografts. Consequently, allograft viability was quickly impaired, leading to irreversible bone damage. This study suggest that 10 Gy of donor total body irradiation delivered six days prior to grafting cannot circumvent the immune rejection in a vascularized allograft of bone across a strong histocompatibility barrier.

Total lymphoid irradiation and discordant cardiac xenografts.

Total lymphoid irradiation can prolong concordant cardiac xenografts. The effects of total lymphoid irradiation in a discordant xenograft model (guinea pig to rat) were studied with and without adjuvant pharmacologic immunosuppression. Inbred Lewis rats were randomly allocated to one of four groups. Group 1 (n = 6) served as a control group and rats received no immunosuppression. Group 2 (n = 5) received triple-drug therapy that consisted of intraperitoneal azathioprine (2 mg/kg), cyclosporine (20 mg/kg), and methylprednisolone (1 mg/kg) for 1 week before transplantation. Group 3 animals (n = 5) received 15 Gy of total lymphoid irradiation in 12 divided doses over a 3-week period. Group 4 (n = 6) received both triple-drug therapy and total lymphoid irradiation as described for groups 2 and 3. Complement-dependent cytotoxicity assay was performed to determine if a correlation between complement-dependent cytotoxicity and rejection-free interval existed. Rejection was defined as cessation of graft pulsation and was confirmed by histologic test results. Only groups 1 and 2 showed a difference in survival (group 1, 6.9 +/- 1.0 minutes; group 2, 14.2 +/- 2.7 minutes, p = 0.02). Although total lymphoid irradiation did decrease complement-dependent cytotoxicity, linear regression revealed no correlation between complement-dependent cytotoxicity and graft survival (coefficient of correlation, 0.30). Unlike concordant cardiac xenografts, total lymphoid irradiation with or without triple-drug therapy does not prolong graft survival.

[Inhibition of rat heart and kidney allograft rejection by photochemical treatment of the recipient]. / Beeinflussung der Abstossungsreaktion allogener Rattenherz- und Nierentransplantate durch eine photochemische Empfängerbehandlung.

After temporary posttransplant PUVA treatment of graft recipients the survival time of rat heart and kidney allografts was significantly prolonged. In the semiallogeneic F1 model all kidney transplant recipients survived without rejection signs. The mechanism of action should be cleared especially the role of cis-urocanic acid and the introduction of the method into clinical organ transplantation is discussed.

Total lymphoid irradiation in heart transplantation: adjunctive treatment for recurrent rejection.

In the face of recurrent heart transplant graft rejection refractory to all conventional immunotherapy, retransplantation is customary treatment. The case of a heart transplant recipient unsuitable for retransplantation whose recurrent rejection was successfully treated with postoperative total lymphoid irradiation is described.

Comparison of fractionated to single-dose total body irradiation in conditioning canine littermates for DLA-identical marrow grafts.

We explored the ability of fractionated total body irradiation (TBI) given at a rate of 7 cGy/min from opposing dual 60Co sources at otherwise lethal doses of 450, 600, 700, 800, and 920 cGy to condition dogs for marrow grafts from DLA-identical littermates. Results were compared with those of a previously reported study using single-dose TBI administered under otherwise identical conditions. Fractionated TBI was less immunosuppressive than single-dose TBI, as evidenced by a significantly higher rate of graft rejection (P = .001). Specifically, sustained allogeneic engraftment was observed in only two of 18 (11%) dogs that received 600 to 800 cGy fractionated TBI as compared with 11 of 17 (65%) dogs that received comparable doses of single-dose TBI. Only at 450 cGy (none of the ten dogs studied had sustained engraftment) and at 920 cGy (four of five dogs that received fractionated and 20 of 21 dogs that received single-dose TBI engrafted) were we unable to find differences between the two modes of radiation. Most dogs that rejected their graft survived with autologous recovery (13 of 22 that received fractionated and eight of 12 that received single-dose TBI; P = .49), presumably the result of extended support provided by the transient allogeneic grafts. We conclude that at equivalent doses fractionated TBI is significantly less effective than single-dose TBI to condition DLA-identical littermate dogs for marrow transplantation. These findings have implications for the design of conditioning programs in clinical transplantation, especially when T-cell-depleted marrow grafts are used.