Zhiping Qian

Passive transfer of alloantibodies restores acute cardiac rejection in IgKO MICE

Background. Alloantibody is an intrinsic component of the immune response to organ transplants. Although alloantibodies have been correlated with decreased graft survival, the mechanisms of alloantibody-mediated injury remain largely undefined in vivo. In the present study, we have established a model of alloantibody-mediated graft injury using B10.A (H-2a) hearts transplanted to wild type (WT) or immunoglobulin knock out (IgKO) C57BL-Igh-6 (H-2b) mice. Methods. Alloantibodies were measured in the circulation and graft by flow cytometry and in immunofluorescence staining, respectively. Intragraft cytokine mRNA expression was evaluated using a competitive template reverse transcriptase polymerase chain reaction (RT-PCR) technique. P-selectin and von Willebrand factor expression were localized by immunoperoxidase staining. The capacity of alloantibodies to restore acute cardiac allograft rejection was tested by passive transfer of monoclonal antibodies (mAbs) against donor major histocompatibility complex (MHC) class I antigens to IgKO recipients. Results. B10.A cardiac allografts are rejected acutely by WT C57BL/6 recipients, but over 50% of the cardiac allografts survived more than 50 days after transplantation in IgKO mice. Competitive template RT-PCR on the cardiac transplants demonstrated similar levels of IL-1-&agr;, IL-12 (p40), TNF-&agr;, IL-2, IFN-&ggr;, IL-4, and IL-10 mRNA in WT and IgKO recipients 8–10 days after transplantation, indicating that macrophage- and T-cell-dependent immune responses were intact in IgKO recipients. The rejection of B10.A hearts in WT recipients was characterized by interstitial and perivascular cellular infiltration; IgG, IgM, and complement (C3) deposition; vascular cell injury and intravascular platelet aggregation; and release of von Willebrand factor and P-selectin. In IgKO recipients the lower degree of vascular injury in the absence of alloantibody responses was reflected by the lack of release of von Willebrand factor and P-selectin, which remained confined to cytoplasmic storage granules of endothelial cells and platelets. Acute rejection of cardiac allografts was restored to IgKO recipients by passive transfer of proinflammatory IgG2b mAbs against donor MHC; recipients injected with isotype-matched control mAbs did not reject. In contrast, passive transfer of IgG1 mAbs against donor MHC failed to restore acute rejection of cardiac allografts to IgKO recipients. Passive transfer of IgG2b, but not IgG1 mAbs was associated with endothelial cell activation and platelet aggregation together with the release of preformed von Willebrand factor and P-selectin from storage granules. Conclusions. Acute rejection of cardiac allografts can be reconstituted in IgKO recipients by passive transfer of IgG2b, but not IgG1 antibody. This model allows the mechanism of alloantibody-mediate graft injury to be dissected in vivo.

Non‐Complement‐ and Complement‐Activating Antibodies Synergize to Cause Rejection of Cardiac Allografts

Alloantibodies (AlloAbs) are a clinically significant component of the immune response to organ transplants. In our experimental model, B10.A (H‐2a) cardiac transplants survived significantly longer in C57BL/6 (H‐2b) immunoglobulin knock‐out (IgKO) recipients than in their wild‐type (WT) counterparts. Passive transfer of a single 50–200‐μg dose of complement‐activating IgG2b AlloAbs to IgKO recipients reconstituted acute rejection of cardiac allografts. Although passive transfer of a subthreshold dose of 25 μg of IgG2b or a single 100–200‐μg dose of non‐complement‐activating IgG1 AlloAbs did not restore acute rejection to IgKO recipients, a combination of these AlloAbs did cause acute graft rejection. Histologically, rejection was accompanied by augmented release of von Willebrand factor from endothelial cells. IgG1 AlloAbs did not activate complement on their own and did not augment complement activation by IgG2b AlloAbs. However, IgG1 AlloAbs stimulated cultured mouse endothelial cells to produce monocyte chemotactic protein 1 (MCP‐1) and neutrophil chemoattractant growth‐related oncogene α (KC). TNF‐α augmented IgG1 induced secretion of MCP‐1 and KC. These findings indicate that non‐complement‐activating AlloAbs can augment injury to allografts by complement‐activating AlloAbs. Non‐complement‐activating AlloAbs stimulate endothelial cells to produce chemokines and this effect is augmented in the milieu of proinflammatory cytokines.

Membrane Attack Complex Contributes to Destruction of Vascular Integrity in Acute Lung Allograft Rejection

The lung is known to be particularly susceptible to complement-mediated injury. Both C5a and the membrane attack complex (MAC), which is formed by the terminal components of complement (C5b-C9), can cause acute pulmonary distress in nontransplanted lungs. We used C6-deficient rats to investigate whether MAC causes injury to lung allografts. PVG.R8 lungs were transplanted orthotopically to MHC class I-incompatible PVG.1U recipients. Allografts from C6-sufficient (C6+) donors to C6+ recipients were rejected with an intense vascular infiltration and diffuse alveolar hemorrhage 7 days after transplantation (n = 5). Ab and complement (C3d) deposition was accompanied by extensive vascular endothelial injury and intravascular release of von Willebrand factor. In contrast, lung allografts from C6-deficient (C6−) donors to C6− recipients survived 13–17 days (n = 5). In the absence of C6, perivascular mononuclear infiltrates of ED1+ macrophages and CD8+ T lymphocytes were present 7 days after transplantation, but vascular endothelial cells were quiescent, with minimal von Willebrand factor release and no evidence of alveolar hemorrhage or edema. Lung allografts were performed from C6− donors to C6+ recipients (n = 5) and from C6+ donors to C6− recipients (n = 5) to separate the effects of systemic and local C6 production. Lungs transplanted from C6+ donors to C6− recipients had increased alveolar macrophages and capillary injury. C6 production by lung allografts was demonstrated at the mRNA and protein levels. These results demonstrate that MAC causes vascular injury in lung allografts and that the location of injury is dependent on the source of C6.

Synergistic deposition of C4d by complement-activating and non-activating antibodies in cardiac transplants

The role of non‐complement‐activating alloantibodies in humoral graft rejection is unclear. We hypothesized that the non‐complement‐activating alloantibodies synergistically activate complement in combination with complement‐activating antibodies. B10.A hearts were transplanted into immunoglobulin knock out (Ig‐KO) mice reconstituted with monoclonal antibodies to MHC class I antigens. In allografts of unreconstituted Ig‐KO recipients, no C4d was detected. Similarly, reconstitution with IgG1 or low dose IgG2b alloantibodies did not induce C4d deposition. However, mice administered with a low dose of IgG2b combined with IgG1 had heavy linear deposits of C4d on vascular endothelium. C4d deposits correlated with decreased graft survival. To replicate this synergy in vitro, mononuclear cells from B10.A mice were incubated with antibodies to MHC class I antigens followed by incubation in normal mouse serum. Flow cytometry revealed that both IgG2a and IgG2b synergized with IgG1 to deposit C4d. This synergy was significantly decreased in mouse serum deficient in mannose binding lectin (MBL) and in serum deficient in C1q. Reconstitution of MBL‐A/C knock out (MBL‐KO) serum with C1q‐knock out (C1q‐KO) serum reestablished the synergistic activity. This suggests a novel role for non‐complement‐activating alloantibodies and MBL in humoral rejection.

C6 Produced by Macrophages Contributes to Cardiac Allograft Rejection

The terminal components of complement C5b-C9 can cause significant injury to cardiac allografts. Using C6-deficient rats, we have found that the rejection of major histocompatibility (MHC) class I-incompatible PVG.R8 (RT1.AaBu) cardiac allografts by PVG.1U (RT1.AuBu) recipients is particularly dependent on C6. This model was selected to determine whether tissue injury results from C6 produced by macrophages, which are a conspicuous component of infiltrates in rejecting transplants. We demonstrated that high levels of C6 mRNA are expressed in isolated populations of macrophages. The relevance of macrophage-produced C6 to cardiac allograft injury was investigated by transplanting hearts from PVG.R8 (C6−) donors to PVG.1U (C6−) rats which had been reconstituted with bone marrow from PVG.1U (C6+) rats as the sole source of C6. Hearts grafted to hosts after C6 reconstitution by bone marrow transplantation underwent rejection characterized by deposition of IgG and complement on the vascular endothelium together with extensive intravascular aggregates of P-selectin-positive platelets. At the time of acute rejection, the cardiac allografts contained extensive perivascular and interstitial macrophage infiltrates. RT-PCR and in situ hybridization demonstrated high levels of C6 mRNA in the macrophage-laden transplants. C6 protein levels were also increased in the circulation during rejection. To determine the relative contribution to cardiac allograft rejection of the low levels of circulating C6 produced systemically by macrophages, C6 containing serum was passively transferred to PVG.1U (C6−) recipients of PVG.R8 (C6−) hearts. This reconstituted the C6 levels to about 3 to 6% of normal values, but failed to induce allograft rejection. In control PVG.1U (C6−) recipients that were reconstituted with bone marrow from PVG.1U (C6−) donors, C6 levels remained undetectable and PVG.R8 cardiac allografts were not rejected. These results indicate that C6 produced by macrophages can cause significant tissue damage.

Accelerated graft arteriosclerosis in cardiac transplants

Background. A critical role for the terminal components of complement (C5b-C9) has been demonstrated previously in acute allograft rejection with the use of C6-deficient PVG congenic rat strains. The C6 deficiency prevents the formation of membrane attack complex (MAC) by C5b-C9. Hearts transplanted from PVG.1A (RT1a) rats are rejected acutely (7–9 days) by fully MHC-incompatible C6-sufficient PVG.1L (RT11) recipients, but they survive significantly longer in untreated C6-deficient PVG.1L recipients (19 to >60 days). Methods. To investigate the contribution of MAC to chronic rejection and accelerated graft arteriosclerosis (AGA) in long-term cardiac allografts, hearts were transplanted heterotopically from PVG.1A donors to C6-sufficient and C6-deficient PVG.1L hosts that were treated with cyclosporine 15 mg/kg/day for 14 days after cardiac grafting. Alloantibody responses in hosts were measured by flow cytometry at 4, 8, 12, and 16 weeks after transplantation. Vigorously contracting grafts were removed at 60 days (n=5) and at 90–128 days (n=12) after surgery for morphological evaluation. Computerized planimetry measurements were made in complete cross-sections of grafts on all assessable arteries larger than 16 microns in diameter. Results. The survival of most (six of seven) cardiac allografts in C6-deficient recipients was prolonged by cyclosporine treatment to greater than 90 days. In contrast, 14 of 25 hearts that were transplanted to C6-sufficient recipients were rejected between 21 and 84 days with severe vascular injury. AGA, defined as smooth muscle cells forming a neointima inside the internal elastic lamina and luminal compromise, affected a greater percentage of arteries in C6-sufficient than in C6-deficient recipients. AGA developed earlier and more frequently in arteries of medium (<100 micron) diameter than those of large diameter in both C6-sufficient and C6-deficient recipients. Serial sections demonstrated the lesions in medium arteries to be located adjacent to the smooth muscle sphincters at the junction of arteriolar branches. Conclusions. These results demonstrate that MAC promotes the pathogenesis of AGA in long-term cardiac allografts.

Terminal complement components mediate release of von Willebrand factor and adhesion of platelets in arteries of allografts

Background. Both humoral and cellular immune responses can cause arterial injury in organ transplants, but the manifestations of these different inflammatory mechanisms have not been dissected fully. The present study was designed to define the effects of the terminal complement components on arterial injury in vivo. Methods. The authors have developed congenic rat strains with a C6 deficiency. The absence of C6 terminates the cascade of complement after C5 cleavage and prevents the assembly of the membrane attack complex. Hearts were transplanted from PVG.1A (RT1a) rats to major histocompatibility complex-incompatible C6-deficient (C6−) or C6-sufficient (C6+) PVG.1U (RT1u) rats. Results. PVG.1A (C6−) cardiac grafts were rejected acutely (6–7 days) by untreated PVG.1U (C6+) recipients but survived significantly longer in PVG.1U (C6−) recipients (8 to >30 days). Arteries of cardiac allografts in C6+ recipients demonstrated extensive endothelial injury evidenced by release of von Willebrand factor (vWF) and accompanied by platelet aggregation. In contrast, vWF was retained in Weibel-Palade storage granules of arterial endothelial cells in cardiac allografts that were rejected by C6− recipients. In the absence of C6, intimal alterations were limited to lifting of endothelial cells from supporting stroma by infiltrating mononuclear cells, duplicating the clinical lesion described as endotheliitis or intimal arteritis. Delaying graft rejection with a short course of cyclosporine did not decrease vWF release and platelet aggregation in PVG.1U (C6+) recipients. Conclusions. Mononuclear cell infiltration of the arterial intima occurs in the absence of C6, but C6 deficiency limits the release of vWF from arterial endothelial cells.

Antibody and complement mediated injury in transplants following sensitization by allogeneic blood transfusion

Background. Many patients on the waiting list for transplants are sensitized from previous blood transfusions, pregnancy, or transplants. We investigated the role of complement in acute and chronic pathology in hearts transplanted to sensitized rats. Methods. Blood was transfused from allogeneic PVG.R8 rats or control isogeneic PVG.1U rats to C6-sufficient and -deficient PVG.1U rats. Three weeks later hearts were transplanted from PVG.R8 donors and low-dose cyclosporin A was initiated. Results. Allogeneic but not isogeneic blood transfusion elicited strong immunoglobulin (Ig) M, IgG1 and IgG2b alloantibody responses. Sensitization caused accelerated acute rejection of cardiac allografts by C6-sufficient recipients (4 days). In contrast, allografts functioned over 40 days in all C6-deficient recipients, but sensitization caused increased interstitial fibrosis and chronic vasculopathy. Circulating alloantibodies were associated with deposits of C4d on the vascular endothelium together with pericapillary accumulation of neutrophils and macrophages in the grafts. In contrast, T cells accumulated in periarterial lymphatics that did not have C4d deposits. Conclusions. Presensitization by allogeneic blood transfusion causes accelerated acute graft rejection in the presence of the complete complement cascade. In the absence of C6, macrophages colocalized with deposits of C4d and T cells accumulated in the periarterial lymphatics.

C4d Deposition and Cellular Infiltrates as Markers of Acute Rejection in Rat Models of Orthotopic Lung Transplantation

Background. C4d is a useful marker of antibody-mediated rejection in cardiac and renal transplants, but clinical studies examining correlations between circulating alloantibodies, C4d deposition, and rejection in lung transplants have yielded conflicting results. Methods. We studied circulating alloantibody levels and C4d deposition in two rat models of lung transplantation: Brown Norway (BN) to Wistar-Kyoto (WKY) and PVG.R8 to PVG.1U lung allografts. The availability of C6 deficient (C6−) and C6 sufficient (C6+) PVG 1U rats allowed evaluation of the effects of the terminal complement components on graft injury and C4d deposition. Results. The lung allografts had histologic features resembling human posttransplant capillaritis, characterized by neutrophilic infiltration of alveoli, edema, and hemorrhage. Immunoperoxidase stains on cross sections of allografts showed intense, diffuse, C4d deposition in a continuous linear pattern on the vascular endothelium. C4d deposits were found in both BN to WKY and PVG R8 to 1U allografts, whereas no staining was detectable in WKY to WKY isografts or native lungs. Complement deposition was associated with vascular disruption in C6+, but not in C6− recipients. The presence of circulating donor-specific alloantibodies was verified by flow cytometry. Cell-specific staining revealed perivascular accumulation of macrophages and T lymphocytes whereas neutrophils were sequestered in the intravascular and alveolar capillary compartments. Conclusions. The deposition of C4d on vascular endothelium as well as the coincident presence of alloantibodies is consistent with previous findings in antibody-mediated rejection of renal and cardiac transplants. Furthermore, the histological features of our allografts support the concept that posttransplant capillaritis is a form of humoral rejection.

Fas-mediated apoptosis in accelerated graft arteriosclerosis

Pathological conditions have been recognized where vessel destruction is a prominent feature of the pathogenic process. One such condition consists of the chronic rejection of blood vessels in transplanted solid organs. Accelerated graft arteriosclerosis (AGA) is a multifactorial process characterized by the concentric proliferation of smooth muscle cells (SMCs) within the intima of the vessel wall of transplanted organs. Proliferation of SMCs within the intima corresponds to a response of these cells to injury. In situations like restenosis post-angioplasty, the mechanism of injury: the mechanical disruption of the tunica media, is evident. However, in the case of AGA, the mechanism of injury has remained elusive. In this report, we provide evidence that injury to SMCs in AGA vessels requires an intact Fas pathway. The resulting damage to the tunica media and internal elastic lamina, in turn, might trigger the proliferation of intimal smooth muscle cells that appear to be less sensitive to Fas mediated killing, particularly when supported by a favorable context of inflammatory cytokines and growth factors, as it is the case in AGA. This pathogenic process results in a absolute loss of functional blood vessels that is not being compensated by an efficient angiogenic response.