T-cell dependent immunogenicity of protein therapeutics: Preclinical assessment and mitigation.

Protein therapeutics hold a prominent and rapidly expanding place among medicinal products. Purified blood products, recombinant cytokines, growth factors, enzyme replacement factors, monoclonal antibodies, fusion proteins, and chimeric fusion proteins are all examples of therapeutic proteins that have been developed in the past few decades and approved for use in the treatment of human disease. Despite early belief that the fully human nature of these proteins would represent a significant advantage, adverse effects associated with immune responses to some biologic therapies have become a topic of some concern. As a result, drug developers are devising strategies to assess immune responses to protein therapeutics during both the preclinical and the clinical phases of development. While there are many factors that contribute to protein immunogenicity, T cell- (thymus-) dependent (Td) responses appear to play a critical role in the development of antibody responses to biologic therapeutics. A range of methodologies to predict and measure Td immune responses to protein drugs has been developed. This review will focus on the Td contribution to immunogenicity, summarizing current approaches for the prediction and measurement of T cell-dependent immune responses to protein biologics, discussing the advantages and limitations of these technologies, and suggesting a practical approach for assessing and mitigating Td immunogenicity.

How current understanding of clearance mechanisms and pharmacodynamics of therapeutic proteins can be applied for evaluation of their drug-drug interaction potential.

Increasing use of therapeutic proteins (TPs) in polypharmacy settings calls for more in-depth understanding of the biological interactions that can lead to increased toxicity or loss of pharmacological effect. Factors such as patient population, medications that are likely to be coadministered in that population, clearance mechanisms of a TP, and concomitant drugs have to be taken into account to determine the potential for drug-drug interactions (DDIs). The most well documented TP DDI mechanism involves cytokine-mediated changes in drug-metabolizing enzymes. Because of the limitations of the current preclinical models for addressing this type of DDI, clinical evaluation is currently the most reliable approach. Other DDI mechanisms need to be addressed on a case-by-case basis. These include altered clearance of TPs resulting from the changes in the target protein levels by the concomitant medication, displacement of TPs from binding proteins, modulation of Fcγ receptor expression, and others. The purpose of this review is to introduce the approach used by Pfizer scientists for evaluation of the DDI potential of novel TP products during drug discovery and development.

Complex pharmacokinetics of a humanized antibody against human amyloid beta peptide, anti-abeta Ab2, in nonclinical species.

PURPOSE: Anti-Aß Ab2 (Ab2) is a humanized monoclonal antibody against amino acids 3-6 of primate (but not rodent) amyloid ß (Aß) and is being evaluated for the treatment of Alzheimer's disease (AD). This study was conducted to predict the human pharmacokinetics of Ab2. METHODS: In vivo PK profile of Ab2 in preclinical species and in vitro mechanistic studies in preclinical and human systems were used for pharmacokinetic predictions. RESULTS: In Tg2576 and PSAPP mice that have ~100-fold higher circulating levels of human Aß compared to humans, elimination of Ab2 was target-mediated, such that exposure was 5-10 fold lower compared to wild-type rodents or to PDAPP mice that have human Aß concentrations in plasma similar to humans. In cynomolgus monkeys, the t(1/2) of Ab2 was faster (<2.5 days) compared to that of the control antibody (~13 days). The fast elimination of Ab2 in cynomolgus monkeys was linked to off-target binding to cynomolgus monkey fibrinogen that was also causing incomplete recovery of Ab2 in cynomolgus monkey serum in blood partitioning experiments. Ab2 had significantly weaker to undetectable binding to human (and mouse) fibrinogen and had good recovery in human serum in blood partitioning experiments. CONCLUSIONS: These data predict that elimination of Ab2 in healthy or AD humans is expected to be slow, with t(1/2) similar to that observed for other humanized antibodies.

Investigation of potential carbohydrate antigen targets for human and baboon antibodies.

BACKGROUND: The continued presence of a primate antibody-mediated response to cells and organs from alpha1,3-galactosyltransferase gene-knockout (GTKO) pigs indicates that there may be antigens other than Gal alpha 1,3Gal (alpha Gal) against which primates have xenoreactive antibodies. Human and baboon sera were tested for reactivity against a panel of saccharides that might be potential antigen targets for natural anti-non-alpha Gal antibodies. METHODS: Human sera (n = 16) and baboon sera (n = 15) of all ABO blood types were tested using an enzyme-linked immunoadsorbent assay for binding of IgM and IgG to a panel of synthetic polyacrylamide-linked saccharides (n = 15). Human sera were also tested after adsorption on alpha Gal immunoaffinity beads. Sera from healthy wild-type (WT, n = 6) and GTKO (n = 6) pigs and from baboons (n = 4) sensitized to GTKO pig organ or artery transplants (of blood type O) were also tested. Forssman antigen expression on baboon and pig tissues was investigated by immunohistochemistry. RESULTS: Both human and baboon sera showed high IgM and IgG binding to alpha Gal saccharides, alpha-lactosamine, and Forssman disaccharide. Human sera also demonstrated modest binding to N-glycolylneuraminic acid (Neu5Gc). When human sera were adsorbed on alpha Gal oligosaccharides, there was a reduction in binding to alpha Gal and alpha-lactosamine, but not to Forssman. WT and GTKO pig sera showed high binding to Forssman, and GTKO pig sera showed high binding to alpha Gal saccharides. Baboon sera sensitized to GTKO pigs showed no significant increased binding to any specific saccharide. Staining for Forssman was negative on baboon and pig tissues. CONCLUSIONS: We were unable to identify definitively any saccharides from the selected panel that may be targets for primate anti-non-alpha Gal antibodies. The high level of anti-Forssman antibodies in humans, baboons, and pigs, and the absence of Forssman expression on pig tissues, suggest that the Forssman antigen does not play a role in the primate immune response to pigs.

An industry perspective on the monitoring of subvisible particles as a quality attribute for protein therapeutics.

Concern around the lack of monitoring of proteinaceous subvisible particulates in the 0.1-10 microm range has been heightened (Carpenter et al., 2009, J Pharm Sci 98: 1202-1205), primarily due to uncertainty around the potential immunogenicity risk from these particles. This article, representing the opinions of a number of industry scientists, aims to further the discussion by developing a common understanding around the technical capabilities, limitations, as well as utility of monitoring this size range; reiterating that the link between aggregation and clinical immunogenicity has not been unequivocally established; and emphasizing that such particles are present in marketed products which remain safe and efficacious despite the lack of monitoring. Measurement of subvisible particulates in the <10 microm size range has value as an aid in product development and characterization. Limitations in measurement technologies, variability from container/closure, concentration, viscosity, history, and inherent batch heterogeneity, make these measurements unsuitable as specification for release and stability or for comparability, at the present time. Such particles constitute microgram levels of protein with currently monitored sizes >or=10 microm representing the largest fraction. These levels are well below what is detected or reported for other product quality attributes. Subvisible particles remain a product quality attribute that is also qualified in clinical trials.

Alpha1,3-galactosyltransferase gene-knockout pigs for xenotransplantation: where do we go from here?

The ability to genetically engineer pigs that no longer express the Galalpha1,3Gal (Gal) oligosaccharide has been a significant step toward the clinical applicability of xenotransplantation. Using a chronic immunosuppressive regimen based on costimulatory blockade, hearts from these pigs have survived from 2 to 6 months in baboons. Graft failure was predominantly from the development of a thrombotic microangiopathy. Potential contributing factors include the presence of preformed anti-nonGal antibodies or the development of low levels of elicited antibodies to nonGal antigens, natural killer (NK) cell or macrophage activity, and inherent coagulation dysregulation between pigs and primates. The breeding of pigs transgenic for an "anticoagulant" gene, such as human tissue factor pathway inhibitor, hirudin, or CD39, or lacking the gene for the prothrombinase, fibrinogen-like protein-2, is anticipated to inhibit the change in the endothelium to a procoagulant state that takes place in the pig organ after transplantation. The identification of the targets for anti-nonGal antibodies and/or human macrophages might allow further genetic modification of the pig, and xenogeneic NK cell recognition and activation may be inhibited by the transgenic expression of human leukocyte antigen molecules and/or by blocking the function of activating NK receptors. The ultimate goal of induction of T-cell tolerance may be possible only if these hurdles in the coagulation system and innate immunity can be overcome.

Prolonged survival of porcine hepatocytes in cynomolgus monkeys.

BACKGROUND & AIMS: Management of patients with liver failure can be a significant medical challenge, and transplantation of the liver is the only definitive therapy. Whole liver allotransplantation is limited by a shortage of human donors and the risks of the surgery in those most ill. Transplants consisting of xenogeneic hepatocytes might overcome these problems, and work in rodents indicates that such transplants can correct some metabolic deficiencies and can prevent the complications and mortality associated with hepatic failure. As a prelude to clinical application, we tested the feasibility of hepatocyte xenotransplantation in nonhuman primates. METHODS: One to 2 billion hepatocytes from outbred swine were transplanted into the spleens of cynomolgus monkeys using conventional immunosuppression to control rejection. Duration of graft function was determined based on assay for porcine albumin. RESULTS: Following a single infusion, xenogeneic hepatocytes functioned for more than 80 days and, following re-transplantation, for more than 253 days. Engraftment in the spleen was confirmed 40 days after transplantation by asialoglycoprotein receptor-directed nuclear scanning. The humoral immune response to the transplanted porcine cells had no discernible impact on the survival of the grafts. CONCLUSIONS: Xenotransplantation of hepatocytes should be explored as a readily available, minimally invasive form of therapy for hepatic failure.

Selected physiologic compatibilities and incompatibilities between human and porcine organ systems.

The shortage of donor organs is a major barrier to clinical organ transplantation. Although xenotransplantation is considered one of the alternatives to human organ transplantation, there are immunologic and physiologic incompatibilities between humans and pigs. With the exception of coagulation, the major potential physiologic incompatibilities relating to function of the kidney, heart, liver, lungs, pancreatic islets, and hormones are reviewed. Some of these physiologic differences can be overcome by producing genetically altered pigs to improve compatibility with humans. The possibility of producing such pigs for organ transplantation is considered.

Antibodies directed to pig non-Gal antigens in naïve and sensitized baboons.

BACKGROUND: As pigs homozygous for alpha1,3-galactosyltransferase gene-knockout (GT-KO) are available, primate antibodies to pig non-Gal antigens can be studied. METHODS: Sera from 56 baboons were tested for binding of IgM and IgG to peripheral blood mononuclear cells (PBMC) from both wild-type (WT) and GT-KO pigs by flow cytometry. Complement-dependent cytotoxicity was measured in 39 sera. Antibody and cytotoxicity responses were measured in two baboons exposed to a GT-KO pig heart, one not immunosuppressed and one that received only cobra venom factor. RESULTS: IgM and IgG bound to 95% and 79% of WT PBMC, and 32% and 9% GT-KO PBMC, respectively (WT vs. GT-KO, P<0.01). Whereas 97% of sera were cytotoxic to WT PBMC, only 64% were cytotoxic to GT-KO PBMC, and the level of cytotoxicity was less (mean 60% vs. 25% lysis, P<0.05). In the two baboons exposed to GT-KO hearts, anti-non-Gal antibodies increased markedly, peaking after 2 (IgM) and 3 (IgG) weeks, associated with an increase in lysis of GT-KO PBMC. CONCLUSIONS: Two-thirds of baboon sera demonstrated cytotoxicity to GT-KO PBMC. After GT-KO organ transplantation, if an elicited antibody response develops, it is likely to cause rapid graft rejection.

Allosensitized humans are at no greater risk of humoral rejection of GT-KO pig organs than other humans.

BACKGROUND: The availability of pigs homozygous for alpha1,3-galactosyltransferase gene-knockout (GT-KO) has enabled study of the incidence and cytotoxicity of primate antibodies directed to antigens other than Galalpha1,3Gal (Gal), termed non-Gal antigens. METHODS: Sera from 27 healthy humans and 31 patients awaiting renal allotransplantation, who were either unsensitized [panel reactive antibodies (PRA) < 10%] or allosensitized (PRA > 70%), were tested by flow cytometry for binding of immunoglobulin M (IgM) and IgG to peripheral blood mononuclear cells (PBMC) from both wild-type (WT) and GT-KO pigs. Complement-dependent cytotoxicity to WT and GT-KO PBMC was also measured. RESULTS: IgM and IgG from all 27 (100%) healthy human sera bound to WT PBMC, while 78% and 63% of these sera had IgM and IgG that bound to GT-KO PBMC, respectively. Mean binding to WT PBMC was significantly greater than GT-KO PBMC. Whereas 100% of sera were cytotoxic to WT PBMC, only 61% were cytotoxic to GT-KO PBMC, and the extent of lysis was significantly less. Neither mean binding of IgM and IgG nor cytotoxicity of unsensitized and allosensitized sera to WT and GT-KO PBMC was significantly different to that of healthy sera. CONCLUSIONS: More than half of the healthy humans tested had cytotoxic antibodies to GT-KO PBMC, but allosensitized patients will be at no greater risk of rejecting a pig xenograft by a humoral mechanism.

Characterization of anti-Gal antibody-producing cells of baboons and humans.

BACKGROUND: Anti-Gal antibodies cause hyperacute and delayed xenograft rejection in pig-to-primate transplantation. The cell populations producing anti-Gal and other natural antibodies in primates are unknown. METHODS: Cells from different lymphoid compartments of naïve or sensitized baboons were examined for anti-Gal and total Ig production by ELISPOT. B and plasma cells from humans and baboons were purified by FACS sorting and characterized for anti-Gal and total Ig production and cytology. RESULTS: In naïve baboons, the spleen was the major source of anti-Gal IgM-secreting cells. Two months after sensitization with porcine tissues, high frequencies of anti-Gal IgM- and IgG-secreting cells were detected in the spleen, lymph nodes, and bone marrow. Six months after antigen exposure, anti-Gal IgM- and IgG-secreting cells were preferentially localized in the bone marrow. Cells from human spleen, bone marrow, and blood were also analyzed and anti-Gal IgM-secreting cells were detected mainly in the spleen. Sorting of baboon and human cells showed that anti-Gal IgM-secreting cells were mainly splenic B cells (CD20+, CD138-, and Ig+). Although low in percentage, sorted CD20-CD138+ plasma cells in spleen and bone marrow secreted large quantities of anti-Gal IgM. Most anti-Gal IgG-secreting cells were plasma cells (CD138+) at both early (Ig+) and late (Ig-) stages of differentiation. CONCLUSIONS: Similar to Gal knockout mice, natural anti-Gal IgM antibodies in primates are produced mainly by splenic B cells. After antigen exposure, anti-Gal IgM and IgG were secreted by both B and plasma cells. These results suggest strategies to remove xenoreactive antibody-secreting cells prior to transplantation.

Incidence and cytotoxicity of antibodies in cynomolgus monkeys directed to nonGal antigens, and their relevance for experimental models.

The recent availability of pigs homozygous for alpha1,3-galactosyltransferase gene-knockout (GT-KO) has enabled the study of incidence and cytotoxicity of antibodies of cynomolgus monkeys directed to antigens other than Galalpha1,3Gal (Gal), termed nonGal antigens. To this aim, sera from 21 cynomolgus monkeys were tested by flow cytometry for binding of IgM and IgG to peripheral blood mononuclear cells (PBMC) from wild-type (WT) and GT-KO pigs. The sera were also tested for complement-dependent cytotoxicity to WT and GT-KO PBMC. Anti-WT IgM and IgG were found in 100% and 95%, respectively, and anti-GT-KO IgM and IgG in 76% and 66%, respectively, in the sera of the monkeys tested (P < 0.01). Whereas 100% of sera were cytotoxic to WT PBMC, only 76% were cytotoxic to GT-KO PBMC, and the level of cytotoxicity was significantly less (P < 0.01). Although the incidence and cytotoxicity of antibodies in monkey sera to GT-KO pig PBMC are significantly less than to WT PBMC, approximately three-quarters of the monkeys tested had cytotoxic antibodies to GT-KO PBMC. This incidence of cytotoxicity is significantly higher than that found in baboons and humans, suggesting the baboon may be an easier and possibly more suitable model to study antibody-mediated rejection of transplanted GT-KO pig organs and cells.

alpha1,3-Galactosyltransferase gene-knockout pig heart transplantation in baboons with survival approaching 6 months.

BACKGROUND: The recent generation of alpha1,3-galactosyltransferase gene-knockout (GalT-KO) pigs has allowed investigation of the survival of GalT-KO pig organs in nonhuman primates. METHODS: Heterotopic heart transplantation from GalT-KO pigs was carried out in baboons (n=8) using a human antihuman CD154 monoclonal antibody-based immunosuppressive regimen. RESULTS: In six of the eight cases, graft survival extended to between approximately 2 and 6 months. All grafts developed thrombotic microangiopathy (TM). In particular, the clinical course of one baboon in which the graft functioned for 179 days is summarized. This baboon received aspirin (40 mg on alternate days) from day 4 in addition to heparin, which may have been a factor in the delay of onset and progression of TM and in prolonged graft survival. Maintenance therapy with anti-CD154 mAb, mycophenolate mofetil, and methylprednisolone was associated with persistently low numbers of CD3CD4 and CD3CD8 cells. Despite persisting depletion of these cells, no infectious complications occurred. CONCLUSIONS: It remains to be established whether TM is related to a very low level of natural preformed or T-cell-induced antibody deposition on the graft, inducing endothelial activation and injury, or to molecular incompatibilities in the coagulation mechanisms between pig and baboon, or to both. However, function of a pig organ in a baboon for a period approaching six months, which has not been reported previously, lends encouragement that the barriers to xenotransplantation will eventually be overcome.

Vascularized thymic lobe transplantation in a pig-to-baboon model: a novel strategy for xenogeneic tolerance induction and T-cell reconstitution.

BACKGROUND: This laboratory has previously demonstrated the induction of allogeneic tolerance by vascularized thymic lobe (VTL) transplantation in miniature swine. We report here our initial attempt to induce tolerance by VTL transplantation in the clinically relevant, discordant, pig-to-baboon model of xenotransplantation. METHODS: Six baboons received xenografts of hDAF VTLs. Four of these baboons also received omental thymic tissue implants. All recipients were treated with an immunosuppressive conditioning regimen that included thymectomy, splenectomy, extracorporeal immunoadsorption of anti-alpha Gal antibodies, and T-cell depletion. Two control baboons received sham operations, of which one also received 5x10 hDAF porcine thymocytes/kg intravenously. RESULTS: Transplanted VTL grafts supported early thymopoiesis of recipient-type immature thymocytes, and facilitated engraftment of nonvascularized thymic omental implants. Recipients of the VTL grafts demonstrated donor-specific unresponsiveness in MLR assays, development of peripheral CD45RAhigh/CD4 double positive (DP) cells, and positive cytokeratin staining of thymic stroma in the grafts for 2 months following xenotransplantation. The control baboons did not show these markers of thymic reconstitution. The eventual return of Gal natural antibodies led to the destruction of graft epithelial cells and the rejection of all VTL grafts by 3 months posttransplantation. CONCLUSIONS: VTL transplantation from hDAF swine to baboons induced early thymopoiesis in the recipients and donor-specific cellular unresponsiveness in vitro. When coupled with additional strategies aimed at silencing humoral rejection, VTL transplantation may significantly prolong xenograft survival and result in long-term tolerance.

Marked prolongation of porcine renal xenograft survival in baboons through the use of alpha1,3-galactosyltransferase gene-knockout donors and the cotransplantation of vascularized thymic tissue.

The use of animal organs could potentially alleviate the critical worldwide shortage of donor organs for clinical transplantation. Because of the strong immune response to xenografts, success will probably depend upon new strategies of immune suppression and induction of tolerance. Here we report our initial results using alpha-1,3-galactosyltransferase knockout (GalT-KO) donors and a tolerance induction approach. We have achieved life-supporting pig-to-baboon renal xenograft survivals of up to 83 d with normal creatinine levels.

Heart transplantation in baboons using alpha1,3-galactosyltransferase gene-knockout pigs as donors: initial experience.

Hearts from alpha1,3-galactosyltransferase knockout pigs (GalT-KO, n = 8) were transplanted heterotopically into baboons using an anti-CD154 monoclonal antibody-based regimen. The elimination of the galactose-alpha1,3-galactose epitope prevented hyperacute rejection and extended survival of pig hearts in baboons for 2-6 months (median, 78 d); the predominant lesion associated with graft failure was a thrombotic microangiopathy, with resulting ischemic injury. There were no infectious complications directly related to the immunosuppressive regimen. The transplantation of hearts from GalT-KO pigs increased graft survival over previous studies.

alpha1,3-Galactosyltransferase gene-knockout miniature swine produce natural cytotoxic anti-Gal antibodies.

BACKGROUND: The expression of galactose alpha 1,3 galactose (Gal) in pigs has proved a barrier to xenotransplantation. Miniature swine lacking Gal (Gal pigs) have been produced by nuclear transfer/embryo transfer. METHODS: The tissues of five Gal pigs of SLA dd haplotype (SLA) were tested for the presence of Gal epitopes by staining with the Griffonia simplicifolia IB4 lectin. Their sera were tested by flow cytometry for binding of IgM and IgG to peripheral blood mononuclear cells (PBMC) from wild-type (Gal) SLA-matched pigs; serum cytotoxicity was also assessed. The cellular responses of PBMC from Gal swine toward Gal SLA-matched PBMC were tested by mixed leukocyte reaction and cell-mediated lympholysis assays. RESULTS: None of the tissues tested showed Gal expression. Sera from all five Gal pigs manifested IgM binding to Gal pig PBMC, and sera from three showed IgG binding. In all five cases, cytotoxicity to Gal cells could be demonstrated, which was lost after treatment of the sera with dithiothreitol, indicating IgM antibody-mediated cytotoxicity. PBMC from Gal swine had no proliferative or cytolytic T-cell response toward Gal SLA-matched PBMC. CONCLUSIONS: Gal pigs do not express Gal epitopes and develop anti-Gal antibodies that are cytotoxic to Gal pig cells. The absence of an in vitro cellular immune response between Gal and Gal pigs is related to their identical SLA haplotype and indicates the absence of immunogenicity of Gal in T-cell responses. The model of Gal organ transplantation into a Gal SLA-matched recipient would be a valuable large animal model in the study of accommodation or B-cell tolerance.

Acute vascular rejection of xenografts: roles of natural and elicited xenoreactive antibodies in activation of vascular endothelial cells and induction of procoagulant activity.

BACKGROUND: Hyperacute rejection of vascularized discordant xenografts can now be effectively managed. However, acute vascular rejection (AVR) then ensues, resulting in graft destruction, coagulopathy, or both within weeks. The aim of this study was to determine associations between humoral responses to the xenograft and the induction of AVR, coagulopathy, or both. METHODS: In vitro, heat-inactivated, naive or sensitized baboon sera containing xenoreactive natural or elicited antibodies were used to activate porcine aortic endothelial cells (PAEC) in vitro. Tissue factor expression on PAEC was determined as an index of heightened procoagulant activity. In vivo, porcine renal xenografts were transplanted into immunosuppressed baboons, and at the time of rejection or the development of a consumptive coagulopathy, biopsy specimens were obtained for studies of xenoreactive antibody binding and tissue factor expression. RESULTS: In vitro, incubation of PAEC with naive baboon sera containing natural anti-Galalpha1,3Gal (Gal) antibodies resulted in minimal tissue factor induction; the addition of complement boosted procoagulant responses. Elicited xenoreactive antibodies, and to non-Gal epitopes alone, induced high amounts of procoagulant activity on PAEC; the addition of complement resulted in overt cytotoxicity. In vivo, AVR was associated with xenoreactive antibody deposition in the graft. When vascular endothelial binding of xenoreactive antibody was combined with the expression of tissue factor, consumptive coagulopathy developed irrespective of histopathologic features of AVR. CONCLUSIONS: Our in vitro results indicate that elicited antibodies, potentially to non-Gal epitopes, induce endothelial cell activation and tissue factor expression; in vivo, a consumptive coagulopathy occurred when there was xenoreactive antibody deposition and increase of tissue factor.

Suppression of natural and elicited antibodies in pig-to-baboon heart transplantation using a human anti-human CD154 mAb-based regimen.

Natural and elicited antipig antibodies (Abs) lead to acute humoral xenograft rejection (AHXR). Ten baboons underwent heterotopic heart transplantation (Tx) from human decay-accelerating factor (hDAF) pigs. Depletion of anti-Galalpha1, 3Gal (Gal) Abs was achieved by the infusion of a Gal glycoconjugate from day-1. Immunosuppression included induction of antithymocyte globulin, thymic irradiation, and cobra venom factor, and maintenance with a human antihuman CD154 mAb, mycophenolate mofetil, and methylprednisolone; heparin and prophylactic ganciclovir were also administered. Pig heart survival ranged from 4 to 139 (mean 37, median 27) days, with three functioning for >50 days. Graft failure (n = 8) was from classical AHXR [4], thrombotic microangiopathy [3], or intragraft thrombosis [1], with death (n = 2) from pneumonia [1], or possible drug toxicity (with features of thrombotic microangiopathy) [1]. Anti-Gal Abs (in microg/mL) were depleted by Gal glycoconjugate before graft implantation from means of 41.3 to 6.3 (IgM) and 12.4-4.6 (IgG), respectively, and at graft excision were 6.3 and 1.7 microg/mL, respectively. No elicited Abs developed, and no cellular infiltration was seen. The treatment regimen was effective in maintaining low anti-Gal Ab levels and in delaying or preventing AHXR. The combination of costimulatory blockade and heparin with Tx of a Gal-negative pig organ may prolong graft survival further.

Initial investigation of the potential of modified porcine erythrocytes for transfusion in primates.

There is a shortage of human blood for transfusion. The possibility of using alpha-galactosidase-treated pig red blood cells (pRBCs) for transfusion into humans has been investigated. pRBCs were treated in vitro with alpha-galactosidase. In vitro binding of antibodies (Abs) in baboon or human sera to untreated/treated pRBCs was assessed by flow cytometry and serum cytotoxicity. In vivo clearance rates of (1) autologous baboon red blood cells (RBCs), (2) unmodified pRBCs, and (3) alpha-galactosidase-treated pRBCs were measured after transfusion into baboons receiving either no treatment or depletion of complement +/- depletion of anti-Gal alpha 1-3Gal (Gal) Ab or of macrophage phagocytes. In vitro binding of baboon or human Abs to treated pRBCs was absent or minimal compared with untreated pRBCs, and serum cytotoxicity was completely inhibited. In vivo autologous baboon RBCs survived for >16 days and unmodified pRBCs for <15 min in an untreated baboon. Treated pRBCs survived for 2 h in an untreated baboon, for 24 h in a complement-depleted baboon, and for 72 h when the baboon was depleted of both complement and anti-Gal Ab, or of complement and macrophage phagocytes. All baboons, however, became sensitized to Gal antigens. Failure to prolong the in vivo survival of treated pRBCs could be due to inadequate removal of Gal epitopes because sensitization to Gal developed, or could imply other, as yet unidentified, causes for RBC destruction. To fully assess the potential of pRBC transfusion in humans, more complete alpha-galactosidase treatment of pRBCs will be required.