Surface modification of pig endothelial cells with a branched heparin conjugate improves their compatibility with human blood

Corline Heparin Conjugate (CHC), a compound of multiple unfractionated heparin chains, coats cells with a glycocalyx-like layer and may inhibit (xeno) transplant-associated activation of the plasma cascade systems. Here, we investigated the use of CHC to protect WT and genetically modified (GTKO. hCD46. hTBM) pig aortic endothelial cells (PAEC) in two pig-to-human in vitro xenotransplantation settings. Model 1: incubation of untreated or hTNFa-treated PAEC with 10% human plasma induced complement C3b/c and C5b-9 deposition, cellular activation and coagulation activation in WT and GTKO. hCD46. hTBM PAEC. Coating of untreated or hTNFa-treated PAEC with CHC (100 mu g/ml) protected against human plasma-induced endothelial activation and damage. Model 2: PAEC were grown on microcarrier beads, coated with CHC, and incubated with non-anticoagulated whole human blood. Genetically modified PAEC significantly prolonged clotting time of human blood (115.0 +/- 16.1 min, p < 0.001) compared to WT PAEC (34.0 +/- 8.2 min). Surface CHC significantly improved the human blood compatibility of PAEC, as shown by increased clotting time (WT: 84.3 +/- 11.3 min, p < 0.001;GTKO. hCD46. hTBM: 146.2 +/- 20.4 min, p < 0.05) and reduced platelet adhesion, complement activation, coagulation activation and inhibition of fibrinolysis. The combination of CHC coating and genetic modification provided the greatest compatibility with human blood, suggesting that pre-transplant perfusion of genetically modified porcine organs with CHC may benefit post-transplant xenograft function

Role of the plasma cascade systems in ischemia/reperfusion injury of bone.

Ischemia/reperfusion (I/R) injury has been extensively studied in organs such as heart, brain, liver, kidney, and lung. As a vascularized organ, bone is known to be susceptible to I/R injury too, but the respective mechanisms are not well understood to date. We therefore hypothesized that, similar to other organs, plasma cascade-induced inflammation also plays a role in bone I/R injury. Reperfusion injury in rat tibia was induced by unilateral clamping of the femoral artery and additional use of a tourniquet, while keeping the femoral vein patent to prevent venous congestion. Rats were subjected to 4h ischemia and 24h reperfusion. Deposition of complement fragment C3b/c and fibrin as well as expression of tissue factor (TF), tissue plasminogen activator (tPA), plasminogen activator inhibitor-1 (PAI-1), and E-selectin was detected by immunohistochemistry. In plasma, the levels of high mobility group box1 (HMGB1) were measured by ELISA. The total level of complement in serum was assessed by the CH50 test. Our results show that deposition of C3b/c was significantly increased with respect to healthy controls in cortical bone as well as in marrow of reperfused limbs. C3b/c deposition was also increased in cortical bone, but not in bone marrow, of contralateral limbs. Deposition of fibrin, as well as expression of PAI-1, was significantly increased in bone after ischemia and reperfusion, whereas expression of tPA was reduced. These differences were most prominent in vessels of bone, both in marrow and cortical bone, and both in reperfused and contralateral limbs. However, PAI-1, was only increased in vessels of reperfused cortical bone and there were no significant changes in expression of E-selectin. With respect to solid bone tissue, a significant increase of C3b/c and fibrin deposition was shown in osteocytes, and for fibrin also in the bone matrix, in both contralateral and reperfused cortical bone compared with normal healthy controls. A slight expression of TF was visible in osteocytes of the normal healthy control group, while TF was not present in the experimental groups. Moreover, CH50 values in serum decreased over time and HMGB1 was significantly increased in plasma of animals at the end of reperfusion. We conclude that ischemia and reperfusion of bone leads to activation of the complement and coagulation systems and a downregulation of the fibrinolytic cascade. In the acute phase, a vascular inflammation induced by activation of the plasma cascade systems also occurs in the bone. This is similar to I/R injury of other vascularized organs and tissues

Porcine extrahepatic vascular endothelial asialoglycoprotein receptor 1 mediates xenogeneic platelet phagocytosis in vitro and in human-to-pig ex vivo xenoperfusion

Asialoglycoprotein receptor-1 (ASGR1) mediates capture and phagocytosis of platelets in pig-to-primate liver xenotransplantation. However, thrombocytopenia is also observed in xenotransplantation or xenoperfusion of other porcine organs than liver. We therefore assessed ASGR1 expression as well as ASGR1-mediated xenogeneic platelet phagocytosis in vitro and ex vivo on porcine aortic, femoral arterial, and liver sinusoidal endothelial cells (PAEC/PFAEC/PLSEC)

Effects of C1 inhibitor on endothelial cell activation in a rat hind limb ischemia-reperfusion injury model.

OBJECTIVE Ischemia-reperfusion (I/R) injury is a major clinical problem linked to vascular surgery. Currently, no drugs to prevent or to treat I/R injury are approved for clinical use. C1 inhibitor (C1 INH) is known to reduce activation of the plasma cascade systems that are involved in the pathophysiologic process of I/R injury. The aim of this study was therefore to investigate the effect of C1 INH on complement deposition and endothelial cell activation in a rat model of hind limb I/R injury. METHODS Male Wistar rats (wild type, bred at the central animal facility, University of Bern), weighing 250 to 320 g, were used. The rats underwent 2-hour ischemia and 24-hour reperfusion by unilateral clamping of the femoral artery and additional use of a tourniquet. Five groups were divided according to intravenous treatment 5 minutes before ischemia: 50 IU/kg C1 INH (n = 5); 100 IU/kg C1 INH (n = 7); vehicle control (n = 5); nontreated control (n = 7); and normal, healthy control without intervention (n = 4). At the end, muscle edema, tissue viability, and histologic features were assessed. Deposition of immunoglobulin M, C1r, C4d, and fibrin and expression of plasminogen activator inhibitor 1, heparan sulfate (HS), E-selectin, and vascular cell adhesion molecule 1 were evaluated by fluorescence staining. In addition, high-mobility group box 1 protein was measured in plasma. RESULTS Edema formation was reduced by C1 INH at two dosages, mirrored by improved histologic injury scores and preserved muscle viability. Deposition of immunoglobulin M, C4d, and fibrin was significantly decreased by 100 IU/kg C1 INH compared with nontreated controls. Pretreatment with 100 IU/kg C1 INH also significantly reduced HS shedding and expression of plasminogen activator inhibitor 1 as well as plasma levels of high-mobility group box 1 protein. CONCLUSIONS Pretreatment with both 50 and 100 IU/kg C1 INH attenuated reperfusion injury of rat hind limbs. Pretreatment with 100 IU/kg also preserved the endothelial HS layer as well as the natural, profibrinolytic phenotype of the endothelium. Prevention of endothelial cell activation by C1 INH may therefore be a promising strategy to prevent I/R injury in the clinical setting of peripheral vascular diseases and elective surgery on extremities

Detection of myocardial necrosis, endothelial dysfunction and inflammation in blood serum.

<p>Blood serum samples obtained at baseline, 50min after ischemia, 10min, 1hour and 2hours after reperfusion were analyzed. for myocardial necrosis by measuring cardiac troponin-I. Endothelial dysfunction was analyzed by measuring CD31 protein levels and inflammation was analyzed by measuring MCP-1, C3b/c and C5b9 levels.</p

Myocardial area at risk and necrosis.

<p>Myocardial area at ischemic risk was compared by expressing the area at ischemic risk as percentage of the left ventricle. Myocardial necrosis was determined by TTC staining and expressed as percentage of the area at ischemic risk.</p

Complement dependent early immunological responses during ex vivo xenoperfusion of hCD46/HLA-E double transgenic pig forelimbs with human blood.

BACKGROUND Besides α1,3-galactosyltransferase gene (GGTA1) knockout, several transgene combinations to prevent pig-to-human xenograft rejection are currently being investigated. In this study, the potential of combined overexpression of human CD46 and HLA-E to prevent complement- and NK-cell-mediated xenograft rejection was tested in an ex vivo pig-to-human xenoperfusion model. METHODS α1,3-Galactosyltransferase knockout heterozygous, hCD46/HLA-E double transgenic (transgenic) as well as wild-type pig forelimbs were ex vivo perfused with whole, heparinized human and autologous pig blood, respectively. Blood samples were analyzed for the production of porcine and/or human inflammatory cytokines as well as complement activation products. Biopsy samples were examined for deposition of human and porcine C3b/c, C4b/c, and C6 as well as CD62E (E-selectin) and CD106 (VCAM-1) expression. Apoptosis was measured in the porcine muscle tissue using TUNEL assays. Finally, the formation of thrombin-antithrombin (TAT) complexes was measured in EDTA plasma samples. RESULTS No hyperacute rejection was seen in this model. Extremity perfusions lasted for up to 12 h without increase in vascular resistance and were terminated due to continuous small blood losses. Plasma levels of porcine cytokines IL1β, IL-6, IL-8, IL-10, TNF-α, and MCP-1 as well as human complement activation markers C3a (P = 0.0002), C5a (P = 0.004), and soluble C5b-9 (P = 0.03) were lower in blood perfused through transgenic as compared to wild-type limbs. Human C3b/c, C4b/c, and C6 as well as CD62E and CD106 were deposited in tissue of wild-type limbs, but significantly lower levels (P < 0.0001) of C3b/c, C4b/c, and C6 deposition as well as CD62E and CD106 expression were detected in transgenic limbs perfused with human blood. Transgenic porcine tissue was protected from xenoperfusion-induced apoptosis (P < 0.0001). Finally, TAT levels were significantly lower (P < 0.0001) in transgenic limb as compared to wild-type limb xenoperfusions. CONCLUSION Transgenic hCD46/HLA-E expression clearly reduced humoral xenoresponses since all, the terminal pathway of complement activation, endothelial cell activation, muscle cell apoptosis, inflammatory cytokine production, as well as coagulation activation, were all downregulated. Overall, this model represents a useful tool to study early immunological responses during pig-to-human vascularized xenotransplantation in the absence of hyperacute rejection

Tissue staining for antibody, complement deposition and damage due to ROS.

<p>Tissue samples were obtained from different sections of the myocardium including area not at ischemic risk (ANR), viable ischemic tissue (VIT) and necrotic ischemic tissue (NIT). The samples were then stained for IgG antibody deposition, C3b/c and C5b9 complement deposition. Damage to the myocardial tissue due to reactive oxygen species was analyzed by staining for 4-hydroxynonenal.</p