Nepal C. Chowdhury

Induction of myocardial nitric oxide synthase by cardiac allograft rejection.

Cardiac transplantation, effective therapy for end-stage heart failure, is frequently complicated by allograft rejection, the mechanisms of which remain incompletely understood. Nitric oxide (NO), a vasodilator which is cytotoxic and negatively inotropic, can be produced in large amounts by an inducible NO synthase (iNOS) in response to cytokines. To investigate whether iNOS is induced during cardiac allograft rejection, hearts from Lewis or Wistar-Furth rats were transplanted into Lewis recipients. At day 5, allogeneic grafts manifested reduced contractility and histologic evidence of rejection (inflammatory infiltrate, edema, necrosis of myocytes). The mRNA for iNOS and iNOS protein were detected in ventricular homogenates and in isolated cardiac myocytes from rejecting allogeneic grafts but not in tissue and myocytes from syngeneic control grafts. Immunocytochemistry showed increased iNOS staining in infiltrating macrophages and in microvascular endothelial cells and cardiac muscle fibers and also in isolated purified cardiac myocytes from the rejecting allografts. Using a myocardial cytosolic iNOS preparation, nitrite formation from L-arginine and [3H] citrulline formation from [3H]L-arginine were increased significantly in the rejecting allogeneic grafts (P < 0.01). Myocardial cyclic GMP was also increased significantly (P < 0.05). The data indicate myocardial iNOS mRNA, protein and enzyme activity are induced in infiltrating macrophages and cardiac myocytes of the rejecting allogeneic grafts. Synthesis of NO by iNOS may contribute to myocyte necrosis and ventricular failure during cardiac allograft rejection.

Induction of transplantation tolerance to rat cardiac allografts by intrathymic inoculation of allogeneic soluble peptides

Since intrathymic (i.t.) injection of UV-B-irradiated spleen cells (SC) or purified resting allogeneic T cells, but not resting B cells, dendritic cells, or macrophages induces specific tolerance in transiently immunosuppressed recipients, we hypothesized that presentation of donor MHC peptide Ag by the host thymic APCs may convey a tolerogenic signal to the recipient. This study examined if i.t. inoculation of allogeneic soluble Ag obtained from 3 M KCl extracts of purified resting T cells can induce specific tolerance to cardiac allografts in transiently immunomodulated recipients. We have now shown that i.t. inoculation of donor soluble Ag on day -7 combined with 1 ml ALS on days -7 and 0 leads to indefinite WF cardiac allograft survival (> 200 days) in Lewis recipients. This finding was reproducible in sublethally irradiated (200 rads TBI) ACI recipients of i.t. Lewis soluble Ag. In contrast, ACI cardiac allografts were promptly rejected in ALS-treated Lewis recipients of i.t. WF soluble Ag, confirming the donor specificity of such immunologic manipulation. Extrathymic inoculation of WF soluble Ag via the intravenous route in controls failed to prevent normal graft rejection in ALS-treated recipients. The long-term unresponsive recipients specifically and permanently accepted donor-type, second-set cardiac allografts. The observation that thymectomy performed 7 days after i.t. Ag injection led to graft rejection strongly suggests that the early phase of induction of donor-specific tolerance is dependent on the presence of donor alloantigens in the host thymus. This approach may have important clinical therapeutic potential in the induction of transplantation tolerance.

EFFECTIVENESS OF INTRATHYMIC INOCULATION OF SOLUBLE ANTIGENS IN THE INDUCTION OF SPECIFIC UNRESPONSIVENESS TO RAT ISLET ALLOGRAFTS WITHOUT TRANSIENT RECIPIENT IMMUNOSUPPRESSION

Our finding that intrathymic inoculation of resting T cells but not dendritic cells induces donor-specific unresponsiveness to organ allografts led us to hypothesize that presentation of MHC class I alloantigens by thymic antigen-presenting cells to T cell precursors during their ontogeny may convey a tolerogenic signal to the recipient. In this study, we examined whether intrathymic inoculation of soluble antigen obtained from 3M KCl extracts of allogeneic T cells could induce donor-specific unresponsiveness to islet allografts in the Lewis-to-WF rat combination. Our results showed that while intrathymic injection of 0.5 mg soluble antigen on day -7 relative to islet transplantation caused acute graft rejection, intrathymic inoculation of 1.0 mg soluble antigen significantly prolonged the survival of Lewis islet allografts from 10.3 +/- 1.1 days in controls to 53.5 +/- 15.6 days (P < 0.001) in naive (nonimmunosuppressed) STZ (streptozotocin)-induced diabetic WF recipients. In contrast, intrathymic inoculation of 2.0 or 4.0 mg soluble Ag on day -7 led to indefinite Lewis islet survival (> 150 days) in all naive diabetic WF recipients; a finding that suggests that 2.0 mg soluble Ag is the optimal effective dose of intrathymic inoculum required to induce donor-specific unresponsiveness in naive recipients in this model. This finding could not be reproduced by intravenous injection of 2.0 mg soluble Ag, thus confirming the privileged position of the thymus in the induction of Ag-specific unresponsiveness. Third-party (BN) islet allografts were rejected in an acute fashion in similarly prepared recipients. Our results suggest that (1) intrathymic inoculation of soluble Ag, unlike cellular Ag, induces donor-specific unresponsiveness to islet allografts without the use of transient recipient immunosuppression; (2) induction of specific unresponsiveness appears to be dose dependent; and (3) the tolerogenic effect of soluble Ag is dependent on the indirect pathway of Ag-presentation in the thymus in the absence of donor antigen-presenting cells in the inoculum. This novel approach of thymic reeducation of adult animals by the deliberate intrathymic inoculation of soluble major histocompatibility complex Ag without the use of recipient immunosuppression may have therapeutic potential in the induction of transplantation tolerance.

cAMP-Mediated Vascular Protection in an Orthotopic Rat Lung Transplant Model Insights Into the Mechanism of Action of Prostaglandin E1 to Improve Lung Preservation

Prostaglandin E1 (PGE1) is often added to the donor pulmonary flush solution to enhance clinical lung preservation for transplantation. Although PGE1 is thought to act as a pulmonary vasodilator during the harvest period, the precise mechanism(s) of action whereby PGE1 enhances lung preservation is unknown. Because cAMP levels decline in endothelial and vascular smooth muscle cells exposed to hypoxia, we hypothesized that a PGE1-mediated increase in cAMP levels within the preserved lungs might improve pulmonary vascular homeostasis following lung transplantation. Rat lungs demonstrated a time-dependent decline in cAMP levels during hypothermic storage, with cAMP levels significantly increased by PGE1 supplementation (approximately 2-fold by 6 hours, P < .0005). To test whether augmenting cAMP levels may enhance lung preservation, experiments were performed using an orthotopic rat left lung transplant model. Compared with controls, supplementing the preservation solution with the membrane-permeable cAMP analogue dibutyryl-cAMP resulted in dose-dependent preservation enhancement, marked by reduced pulmonary vascular resistance (6.0-fold, P < .01), improved arterial oxygenation (3.0-fold, P < .01), reduced graft neutrophil infiltration (1.5-fold, P < .05), and improved recipient survival (7.0-fold, P < .005). Similar preservation enhancement was observed with another cAMP analogue (8-bromo-cAMP) or the phosphodiesterase inhibitor indolidan. Stimulating the cAMP second messenger system by PGE1 supplementation resulted in marked hemodynamic benefits and improved recipient survival, in parallel with reduced graft neutrophil infiltration, vascular permeability, and platelet deposition. These beneficial effects of PGE1 were abrogated by simultaneous administration of the cAMP-dependent protein kinase antagonist Rp-cAMPS. Although an arterial vasodilator (minoxidil) resulted in significant pulmonary vasodilation during harvest, it lacked other nonvasodilating effects of PGE1 and resulted in poor preservation. These data show that harvest vasodilation by itself is insufficient to enhance lung preservation and that PGE1 enhances lung preservation by stimulating the cAMP-dependent protein kinase and promoting non-vasodilatory mechanisms of pulmonary protection.

Enhanced Preservation of Orthotopically Transplanted Rat Lungs by Nitroglycerin but Not Hydralazine Requirement for Graft Vascular Homeostasis Beyond Harvest Vasodilation

Nitric oxide (NO) produced within the lungs maintains pulmonary vascular homeostatic properties, modulating leukocyte traffic, platelet aggregation, and vasomotor tone. Because reactive oxygen intermediates generated during reperfusion react rapidly with available NO, we hypothesized that the NO donor nitroglycerin (NTG) would enhance lung preservation for transplantation by improving graft blood flow and reducing graft neutrophil and platelet sequestration. By use of an orthotopic rat left lung transplant model, with ligation of the native right pulmonary artery to ensure that recipient survival and physiological measurements depend entirely on the transplanted lung, transplants were performed in 70 male Lewis rats after 6-hour 4 degrees C preservation in Euro-Collins solution (EC) alone or EC with supplemental NTG. Compared with EC alone, supplemental NTG significantly increased pulmonary arterial flow (2.2 +/- 1.4 to 21.4 +/- 2.9 mL/min, P < .01), decreased pulmonary vascular resistance (7.4 +/- 2.0 to 1.4 +/- 0.1 x 10(3) Woods units, P < .05), improved arterial oxygenation (163 +/- 57 to 501 +/- 31 mm Hg, P < .01), and enhanced recipient survival (17% to 100%, P < .001). These beneficial effects of NTG were dose dependent over a range of 0.001 to 0.1 mg/mL. Although NTG caused significant pulmonary vasodilation during the harvest/flushing period, the direct-acting vasodilator hydralazine caused greater vasodilation than did NTG but was associated with poor graft function, elevated pulmonary vascular resistance, and poor recipient survival. To explore nonvasodilator protective mechanisms of NTG, graft neutrophil and platelet sequestration were studied; supplemental NTG significantly reduced both neutrophil and platelet accumulation compared with either hydralazine or EC alone.(ABSTRACT TRUNCATED AT 250 WORDS)

Nitroglycerin maintains graft vascular homeostasis and enhances preservation in an orthotopic rat lung transplant model

Transplanted lungs often fail during the peritransplantation period for poorly understood reasons. Because the nitric oxide pathway regulates pulmonary vascular tone, helps to maintain the integrity of the endothelial barrier, and modulates neutrophil adhesivity and activation, we hypothesized that perturbation of this pathway during the preservation and reperfusion of transplanted lungs might play a critical role in mediating early graft failure. To evaluate whether supplementing the preservation solution with the nitric oxide donor nitroglycerin enhances lung preservation for transplantation, we obtained hemodynamic measurements in a model of orthotopic left lung transplantation in the rat after ligation of the native right pulmonary artery. In these experiments, recipient survival and hemodynamics depended solely on the transplanted lung. The left lung was harvested from 22 rats, flushed with either lactated Ringers solution alone (control, n = 11) or Ringers solution supplemented with nitroglycerin (0.1 mg/ml, n = 11), preserved for 4 hours at 4 degrees C, and then transplanted using a rapid cuff technique for bronchial and vascular anastomoses. Nitroglycerin significantly improved arterial blood oxygenation (339 +/- 66 versus 130 +/- 12 mm Hg, p < 0.05), increased pulmonary arterial flow (7.6 +/- 1.9 versus 0.9 +/- 0.2 ml/min, p < 0.005), decreased pulmonary vascular resistance (1.7 +/- 0.4 versus 6.6 +/- 1.9 x 10(3) Wood units, p < 0.05), and enhanced recipient survival (64% versus 0%, p < 0.05). Control grafts had significantly greater neutrophil accumulation (50% greater as quantified by myeloperoxidase activity, p < 0.05) than grafts preserved in the presence of nitroglycerin. These studies show that supplementation of the preservation solution with the nitric oxide donor nitroglycerin maintains graft vascular homeostasis and significantly improves pulmonary function and recipient survival after transplantation.

Acquired systemic tolerance to rat cardiac allografts induced by intrathymic inoculation of synthetic polymorphic MHC class I allopeptides.

This study extends the finding that intrathymic (IT) injection of 3M KC1 extracts of T cells induces transplant tolerance to the use of well defined polymorphic MHC class I allopeptides derived from the hypervariable domain of RT1.Au (WF MHC class I). While three of the six synthetic RT1.Au peptides were immunogenic, three others were nonimmunogenic when tested in ACI responders. In our initial studies, we examined the effects of IT injection of a mixture of equal concentrations of the three nonimmunogenic RT1.Au peptides on WF cardiac allograft survival in ACI recipients. The results showed that a single IT injection of 100 and 300 microg class I MHC allopeptides on day -7 relative to cardiac transplant did not significantly prolong graft survival in naive ACI recipients (MST of 9.8, and 12.3 days vs. 10.5 days in controls). In contrast, 600 microg allopeptides injected IT resulted in modest prolongation of graft to an MST of 19.5 days. However, IT injection of 600 microg allopeptides combined with 0.5 ml ALS on day -7 led to permanent acceptance (>200 days) of cardiac allografts in 7/9 ACI recipients compared with survival of 24.2 days in ALS alone treated controls. In contrast, similar treatment led to acute rejection of third party (Lewis) cardiac allografts. Intravenous injection of 600 microg allopeptides combined with ALS did not result in prolonged graft survival (26.8 days). The long-term unresponsive ACI recipients (>100 days) challenged with second-set cardiac grafts accepted permanently donor-type (WF) grafts while rejecting the third party (Lewis) grafts, a finding that confirms acquired systemic tolerance. These findings confirm the role of IT injection of synthetic polymorphic allopeptides in the induction of acquired thymic tolerance and provide the rationale for testing this strategy in large animals and eventually in man.

Induction of donor-specific unresponsiveness to rat cardiac allografts by intrathymic injection of UV-B-irradiated donor spleen cells

This study examined the role of intrathymic injection of allogeneic spleen cells in induction of donor-specific unresponsiveness to heart allografts in the Lewis-to-ACI rat combination. Intrathymic injection of naive Lewis SC led to rejection in naive or sublethally irradiated (200 rads TBI) ACI recipients at times equivalent to those obtained in control animals. Intrathymic injection of UV-B-irradiated Lewis SC, on the other hand, led to indefinite cardiac allograft survival (>300 days) in sublethally irradiated ACI recipients; similar treatment failed to prevent rejection of third-party (Wistar Furth) cardiac allografts, which demonstrates the specificity of the immunologic unresponsiveness thus induced. The finding that intrathymic injection of untreated allogeneic SC does not prevent rejection of subsequently transplanted allograft suggests that modulation of major histocompatibility complex class II molecule by methods such as UVB may be critical to induction of unresponsiveness. Inoculation of UV-B donor SC in extrathymic sites (subcutaneous, intraperitoneal and intratesticular) did not significantly prolong graft survival in similarly prepared animals, thus confirming the privileged position of the thymus in the induction of tolerance. When the unresponsive recipients of cardiac allografts were made diabetic at 100 days and rechallenged with a second-set donor-type neovascularized pancreatic islet grafts, three of four animals accepted permanently (>100 days) the islet grafts, thus indicating tolerance to donor alloantigens. To define the underlying mechanisms of specific tolerance in this model, in vitro MLR and in vivo adoptive transfer studies failed to demonstrate suppressor activity in the long-term cardiac allograft recipients. In contrast CML assays using 51Cr-release showed that T cells obtained from the unresponsive animals had no detectable cytotoxic activity to Con A-stimulated donor blast targets. The latter finding suggests clonal anergy or deletion of cytotoxic T cells to donor alloantigens. Our results confirm the role of the thymus as a privileged site for the induction and maintenance of specific immunologic unresponsiveness to organ allografts and suggest that this approach may be potentially useful in clinical transplantation of immediately vascularized allografts and neovascularized grafts.

Induction of donor-specific unresponsiveness to rat cardiac allografts by pretreatment with intrathymic donor MHC class I antigens

Since intrathymic injection of UV-B-irradiated spleen cells induces donor-specific unresponsiveness in the sub-lethally irradiated (200 rads TBI) recipients, while intrathymic injection of naive SC leads to acute graft rejection, we hypothesized that presentation of MHC class I rather than MHC class II antigens to immature T cells in the thymus may convey a tolerogenic signal to the recipient. The present study was designed to examine if intrathymic injection of naive MHC class I—positive resting T lymphocytes can induce antigen-specific unresponsiveness to cardiac allografts in the Lewis-to-ACI rat combination. The results showed that intrathymic injection of resting Lewis T cells consistently induced indefinite graft survival (>300 days) in sublethally irradiated (200 rads TBI) ACI recipients while similar treatment failed to prevent the rejection of third-party (Wister-Furth) cardiac allografts, thus demonstrating the specificity of the immunologic unresponsiveness to donor alloantigens. Examination of the timing of intrathymic antigen presentation relative to cardiac transplantation that would achieve 100% permanent graft survival in the Lewis-to-ACI rat combination showed that the optimal time was 7 days before allografting, while peritransplant and immediate post-transplant intrathymic inoculation of donor T cells was relatively ineffective in the induction of unresponsive-ness to donor grafts. We also showed that removal of the antigen-containing thymus in the sublethally irradiated recipients with functioning cardiac allografts consistently caused graft rejection if performed earlier than 21 days after heart transplantation; thymectomy after 21 days of organ transplantation did not affect indefinite survival of the grafts. Thus, it appears that the maintenance of peripheral tolerance to the grafts after 21 days of transplantation may be dependent on the presence of a new clone of antigen-specific tolerant host T cells. These results confirm the immunologic privileged position of the thymus in the induction of central and peripheral tolerance, and suggest that pretreatment with intrathymic MHC class I alloantigens is potentially useful in the induction of unresponsiveness to donor vascularized allografts in adult animals and in man.

Mechanism of acquired thymic tolerance induced by a single major histocompatibility complex class I peptide with the dominant epitope : Differential analysis of regulatory cytokines in the lymphoid and intragraft compartments

BACKGROUND We have recently shown that intrathymic injection of a combination of immunogenic WAG-derived or Wistar-Furth (WF) (RT1.Au) major histocompatibility complex class I peptides induces acquired systemic tolerance to cardiac and islet allografts in the WF-to-ACI rat combination and therefore hypothesized that identification of the class I peptide dominance may play an important role in the induction of antigen (Ag)-specific tolerance. This study defined the peptide with the dominant epitope among the seven synthetic RT1.Au peptides and analyzed the immunoregulatory cytokines within the lymphoid and intragraft compartments associated with acquired thymic tolerance. METHODS ACI recipients were pretreated with intrathymic (IT) injection of 300 microg of the individual seven RT1.Au peptides 7 days before WF or Lewis cardiac transplantation. Cytokine profile of mixed lymphocyte reaction supernatants of T cells obtained from the thymus, mesenteric lymph nodes, spleen, peripheral blood leukocytes, and graft infiltrating cells after donor (WF) or third-party (Lewis) Ag stimulation were measured by enzyme-linked immunosorbent assay, whereas cytokine gene expression was determined by reverse transcription-polymerase chain reaction. RESULTS Only IT injection of peptide 5 (93-109) among the seven RT1.Au peptides induced donor-spe cific tolerance to cardiac allografts in the WF-to-ACI rat combination. In addition, intravenous injection of peptide 5 did not prolong WF graft survival in ACI recipients. Analysis of cytokine production by the tolerant recipients showed significant Ag-specific reduction in the production of interleukin (IL)-2 and interferon-gamma (IFN-gamma) in the thymus, mesenteric lymph nodes, spleen, and peripheral blood leukocytes, which was not associated with a concomitant Ag-specific increase in IL-4 and IL-10 production. Measurement of cytokine mRNA expression confirmed undetectable