Induction of specific allograft immunity by soluble class I MHC heavy chain protein produced in a baculovirus expression system

The PLAC1 protein localizes to membranous compartments in the apical region of the syncytiotrophoblast

PLAC1 is a trophoblast-specific gene that maps to a locus on the X-chromosome important to placental development. We have previously shown that PLAC1 gene expression is linked to trophoblast differentiation. The objective of this study was to define the localization of the PLAC1 polypeptide as a prerequisite to understanding its function. Polyclonal antibodies specific for the putative PLAC1 polypeptide were generated. The subcellular localization of PLAC1 in the trophoblast was examined by immunohistochemical analysis of human placenta complemented by immunoblot analysis of subcellular fractions. Brightfield immunohistochemical analysis of placental tissue indicated that the PLAC1 protein localizes to the differentiated syncytiotrophoblast in the apical region of the cell. Deconvlution immunofluorescence microscopy confirmed localization to the apical region of the syncytiotrophoblast. Its distribution included both intracellular compartments as well as loci in close association with the maternal-facing, microvillous brush border membrane (MVM). These findings were supported by immunoblot analysis of subcellular fractions. A 30 kDa band was associated with the microsomal fraction of placental lysates but not the mitochondrial, nuclear, or soluble fractions, suggesting PLAC1 is targeted to a membrane location. Plasma membranes were obtained from the fetal-facing, basal surface (BM) and the maternal-facing, MVM of the syncytiotrophoblast membrane. PLAC1 immunoreactivity was only detected in membrane fractions derived from the apical MVM consistent with immunohistochemical analyses. These data demonstrate that the PLAC1 protein is restricted primarily to the differentiated trophoblast, localizing to intracellular membranous compartment(s) in the apical region of the syncytiotrophoblast and associated with its apical, microvillous membrane surface.

MHC/peptide tetramer-based studies of T cell function

Direct visualization and quantification of antigen-specific T cells using major histocompatibility complex (MHC)/peptide tetramer technology offers a powerful means to study specific T cell populations of interest. In combination with functional assays, this technology has already provided many new insights into several long-standing immunological concepts in basic science as well as clinical settings.

Allochimeric class I MHC molecules prevent chronic rejection and attenuate alloantibody responses

BACKGROUND

We have shown that treatment with molecularly engineered, allochimeric [alpha1 hl/u]-RT1.Aa class I MHC antigens bearing donor-type Wistar-Furth (WF, RT1.Au) amino acid substitutions for host-type ACI (RTI.Aa) sequences in the alpha1-helical region induces donor-specific tolerance to cardiac allografts in rat recipients. This study examined the effect of allochimeric molecules on the development of chronic rejection.

METHODS

Allochimeric [alpha1 hl/u]-RT1.Aa class I MHC antigenic extracts (1 mg) were administered via the portal vein into ACI recipients of WF hearts on the day of transplantation in conjunction with subtherapeutic oral cyclosporine (CsA, 10 mg/kg/day, days 0-2). Control groups included recipients of syngeneic grafts and ACI recipients of WF heart allografts treated with high-dose CsA (10 mg/kg/day, days 0-6).

RESULTS

WF hearts in ACI rats receiving 7 days of CsA exhibited myocardial fibrosis, perivascular inflammation, and intimal hyperplasia at day 80. At day 120, these grafts displayed severe chronic rejection with global architectural disorganization, ventricular fibrosis, intimal hyperplasia, and progressive luminal narrowing. In contrast, WF hearts in rats treated with [alpha1 hl/u]-RT1.Aa molecules revealed only mild perivascular fibrosis, minimal intimal thickening, and preserved myocardial architecture. Alloantibody analysis demonstrated no IgM alloantibodies in all groups. An attenuated, but detectable, anti-WF IgG response was present in recipients receiving allochimeric molecules, with IgG1 and IgG2a subclasses predominating. Immunohistochemical analysis of allografts demonstrated minimal T cell infiltration and IgG binding to vascular endothelium.

CONCLUSION

Treatment with allochimeric molecules prevents the development of chronic rejection. Such effect may be in part caused by deviation of host alloantibody responses.

Antigen-specific blockade of T cells in vivo using dimeric MHC peptide

Ag-specific immune tolerance in clinical organ transplantation is currently an unrealized but critical goal of transplant biology. The specificity and avidity of multimerized MHC-peptide complexes suggests their potential ability to modulate T cell sensitization and effector functions. In this study, we examined the ability of MHC-peptide dimers to modulate T cell function both in vitro and in vivo. Soluble MHC dimers induced modulation of surface TCR expression and inhibited T cell cytolytic activity at nanomolar concentrations in vitro. Furthermore, engagement of TCR by soluble dimers resulted in phosphorylation of the TCR zeta-chain and recruitment and phosphorylation of zeta-associated protein-70 to the signaling complex, the latter of which increased upon dimer cross-linking. Significantly, Ag-specific inhibition of an alloreactive TCR-transgenic T cell population in vivo resulted in consequent outgrowth of an allogeneic tumor. The prolonged Ag-specific suppression of expansion and/or effector function of cognate T cells in vivo suggests that soluble MHC dimers may be a means of inducing sustained Ag-specific T cell unresponsiveness in vivo.

Use of allochimeric proteins to mitigate graft-versus-host and host-versus-graft immune responses to rat small bowel allografts

BACKGROUND

We aimed to identify the polymorphic epitopes that mitigate graft-versus-host disease (GvHD) and host-versus-graft response (HvGR) toward rat small bowel allografts in rats.

METHODS

We tailored class I major histocompatibility complex (MHC) allochimeric antigens encoding 10 al-helical (alpha(1h)l58-80-RT1.Aa) or 4 (alpha(1h)l/u62-69-RT1.Aa) polymorphic amino acids. In the GvHD model, ACI (RT1a) donors were pretreated (day -14) with an intrathymic injection of alpha(1h)l58-80-RT1.Aa, alpha(1h)l/u62-69-RT1.Aa, or RT1.Al protein, with or without simultaneous intravenous injection of anti-T-cell receptor R73 monoclonal antibodies. Wistar-Furth (WF; RT1u) donors were tested with a similar protocol. In the HvGR model, ACI recipients were treated with a protocol designed to induce transplantation tolerance toward WF heart allografts: a portal vein injection of alpha(1h)l/u62-69-RT1.Aa protein and cyclosporine (4 mg/kg, intramuscular; days 0-6).

RESULTS

GvHD was prevented in all (ACI x LEW) F1 recipients (RT1a/l) by pretreating ACI donors with R73 monoclonal antibody and recipient RT1.Al or alpha(1h)l58-80-RT1.Aa protein. Similarly, pretreatment of WF donors with RT1.Aa protein also prevented GvHD in (ACI x WF) F1 recipients. However, in a combined GvHD/HvGR model, ACI recipient perioperative treatment designed to prevent HvGR only modestly prolonged WF small bowel allograft survival (27.7+/-5.3 days compared to 17.4+/-4.6 days in the cyclosporine-alone group). In contrast, application of the two protocols significantly prolonged WF allograft survival (55.6+/-34.6 days), with two of seven recipients surviving more than 100 days.

CONCLUSION

Simultaneous inhibition of GvHD and HvGR significantly prolongs small bowel allograft survival.

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

Regulatory T cells maintain peripheral tolerance to islet allografts induced by intrathymic injection of MHC class I allopeptides

Although transplantation remains the treatment of choice for diabetes mellitus, immunological rejection of allografts continues to be a major problem. The search for strategies to prevent graft rejection led us to examine if the fate of developing T cells may be influenced by the presence of allo MHC class I peptides in the thymus because T cell receptor-MHC class I/self-peptide interaction regulates thymocyte development. We studied the effects of intrathymic (IT) injection of a short segment of a synthetic immunogenic MHC class I peptide (peptide 2, residues 67-85) of the hypervariable domain of RT1.A derived from WAG rat (RT1U) on islet graft survival in the WF(RT1U)-to-ACI combination. Adult diabetic male recipients were treated with IT injection of a single WAG-derived MHC class I peptide 7 days before intraportal islet transplantation. Long-term unresponsive islet recipients were examined for the development of alloantigen (Ag)-specific regulatory cells. The results showed that while IT injection of 150 microg peptide 2 on day -7 did not prolong graft survival in naive recipients [median survival time (MST) of 14.0 days vs. 9.6 in controls], IT injection of 300 or 600 microg peptide 2 led to normoglycemia and permanent islet survival (> 200 days) in 4/6 and 3/5 STZ-induced diabetic ACI recipients, respectively. IT injection of 150, 300, or 600 microg peptide 2 combined with 0.5 antilymphocyte serum (ALS) immunosuppression on day -7 led to 100% permanent islet allograft survival (> 200 days) compared to MST of 15.0 +/- 2.3 days in ALS alone-treated controls. Similarly prepared animals rejected third-party Brown Norway (BN) islets in an acute fashion, thus demonstrating donor specificity. Intravenous injection of 300 microg peptide 2 combined with 0.5 ml ALS did not prolong islet allograft survival. The long-term unresponsive islet allograft recipients challenged with second set grafts accepted permanently 100% donor-type cardiac allografts while rejecting third-party (BN) hearts without rejecting the primary Wistar Furth (WF) islets. In analyzing the underlying mechanisms of acquired systemic tolerance, we found no suppressor/regulatory cells in adoptive transfer studies in tolerant animals at 30 days after IT injection of allopeptides. In contrast, adoptive transfer of 5 x 10(7) unseparated spleen cells from tolerant animals at 60 and 100 days after islet transplantation into lightly irradiated [200 rad total body irradiation (TBI)] ACI recipients led to donor-specific permanent islet graft survival in 2/3 and 4/5 secondary recipients, respectively, compared to an MST of 13.8 days in lightly irradiated ACI given unmodified syngeneic spleen cells. In addition, adoptive transfer of 2 x 10(7) purified T cells obtained from long-term functioning islet recipients led to permanent donor-specific islet survival in secondary recipients. The finding that IT injection of a short segment of a synthetic immunodominant MHC class I peptide derived from WAG that shares the RT1.A(U) domain with the graft donor is capable of inducing acquired systemic tolerance to WF islets suggests that linked recognition or epitope suppression may be involved in the induction of unresponsiveness. Generation of peripheral Ag-specific regulatory cells that suppress Ag-specific alloreactive T cells is, in part, responsible for the maintenance of tolerance in this model.

Comparative studies of specific acquired systemic tolerance induced by intrathymic inoculation of a single synthetic Wistar-Furth (RT1U) allo-MHC class I (RT1.AU) peptide or WAG (RT1U)-derived class I peptide

BACKGROUND

Because T cell receptor-MHC class I/self-peptide interactions regulate T-cell development, the presence of MHC allopeptides in the thymus may influence T-cell tolerance to alloantigens. This hypothesis is supported by our most recent finding that intrathymic (IT) inoculation of nonimmunogenic synthetic peptides derived from "WAG" RT1.A induces tolerance to cardiac allografts in the Wistar-Furth (WF)-to-ACI model. To evaluate whether in vivo immunogenicity of MHC peptides is relevant to tolerance induction and to examine the effect of peptide specificity, we compared the effects on graft survival of well-defined, strain-specific immunogenic WF MHC class I peptides (RT1.AU) with closely related but non-strain-specific class I peptides derived from WAG (RT1U).

METHODS

In vivo immunization of seven MHC class I peptides synthesized from RT1.AU sequences showed that two (u-5 and u-7) were immunogenic, whereas five others were not immunogenic in ACI recipients. We then examined the effects on cardiac allograft survival in the WF-to-ACI model of the two immunogenic RT1.AU peptides (u-5 and u-7) and three immunogenic WAG-derived peptides (peptides 1, 2, and 5).

RESULTS

A combination of equal amounts (150 microg or 300 microg) of u-5 or u-7 each with 0.5 ml of antilymphocyte serum (ALS) on day -7 led to 60% and 100% permanent graft survival (>150 days), respectively. IT injection of the individual peptides on day -7 showed that only 300 microg of u-5 significantly prolonged graft survival to a median survival time of 17.3 days from 10.5 days in naive recipients. IT injection of 150, 300, and 600 microg of u-5 combined with 0.5 ml of ALS on day -7 led to permanent graft survival (> 150 days) in four of six, nine of nine, and six of six ACI recipients, respectively, compared with a median survival time of 15.4 days in ALS alone-treated controls. In contrast, similar treatments with peptide u-7 with or without 0.5 ml of ALS did not prolong graft survival, thus demonstrating that peptide u-5 alone mediates the observed effects on graft prolongation. A total of 300 microg of u-5 injected IT combined with ALS led to acute rejection of third-party (Lewis) grafts. Intravenous injection of 300 microg of u-5 with ALS also did not prolong WF graft survival in ACI recipients. The long-term unresponsive ACI recipients accepted permanently donor-type (WF) but not third-party (Lewis) second-set cardiac and islet allografts. Similarly, we showed that although IT injection of 600 and 1200 microg of a mixture of immunogenic WAG-derived peptides 1, 2, and 5 combined with 0.5 ml of ALS on day -7 led to permanent WF graft survival in ACI, only IT injection of 300 microg of peptide 2 combined with ALS led to permanent graft survival (>150 days) in four of five animals. To define the underlying mechanisms of tolerance, we examined in vitro the mixed lymphocyte reaction (MLR), cell-mediated lymphocytotoxicity, and cytokine profile of unresponsive recipients. Although the results showed nonspecific T-cell suppression in the MLR at 25 days after transplantation, which correlated with the persistence of ALS immunosuppression, long-term unresponsive animals showed normal MLR to donor and third-party antigens. In contrast, the donor-specific reactive cytotoxic T lymphocytes remained suppressed in short-term and long-term unresponsive rats.

CONCLUSION

Of interest is our finding that IT injection of a short segment of WAG-derived MHC class I peptide induces active acquired tolerance similar to results obtained with the use of pure WF-derived peptide u-5 in the WF-to-ACI rat combination. It is noteworthy that we could not confirm the T helper (Th)1/Th2 paradigm in this model by initial cytokine analysis. Whether induction of tolerance by IT injection of allo-MHC peptides will have clinical usefulness must await results of similar studies in large animals. However, of major interest is the finding that a short segment of RT1.AU represents the tolerogenic

Modulation of alloimmunity to major histocompatibility complex class I by cotransfer of cytokine genes in vivo

Major histocompatibility complex (MHC) class I antigen is a potent stimulus for alloimmune responses and is the principal immunologic target mediating acute cellular rejection of allografts. Using a method of direct in vivo gene transfer of cDNA encoding donor type MHC class I, we showed in a rat model that recipient muscle could express the transferred MHC class I cDNA, resulting in alloimmunization of the recipient. This was most graphically demonstrated by accelerated rejection of cardiac allografts expressing the same MHC class I as encoded by the immunizing cDNA. We now report the use of the particle-mediated gene transfer via a gene gun (Geneva, Middleton, WI, USA) to transfer MHC class I, as well as cytokine gene expression vectors, into rat skin. Compared to intramuscular injection, gene gun transfer to skin resulted in more efficient immunization. Donor-specific cytotoxic T lymphocyte (CTL) responsiveness and antibody levels increased. Furthermore, coexpression of certain cytokine genes with the MHC class I cDNA modulated the immune response. Specifically, coimmunization with IL-10 cDNA abrogated immunity to allo-MHC class I, while coimmunization with GM-CSF cDNA enhanced it. The influence of expression of these genes in skin was demonstrated by alteration of donor cardiac allograft survival. This model is useful for induction and modulation of alloimmune responses and may be used to develop gene therapy strategies to modify them.

Indirect T Cell Allorecognition and Alloantibody-Mediated Rejection of MHC Class I-Disparate Heart Grafts

Recent studies in the rat have identified a role for T cell-dependent alloantibody in rejection of MHC class I-disparate allografts. RT1Aa-disparate PVG.R8 heart grafts are rejected acutely in naive, and hyperacutely in sensitized, PVG.RT1u recipients by CD4 T cell-dependent alloantibody. Here, we examined the T cell Ag recognition pathways responsible and show that direct injection into skeletal muscle of plasmid DNA, encoding a water-soluble form of the RT1Aa MHC class I heavy chain (pcmu-tAa), stimulates IgG2b cytotoxic alloantibody and markedly accelerates rejection of PVG.R8 heart grafts (median survival time 2 days). pcmu-tAa injection did not induce CTL to Aa, arguing against direct allorecognition of soluble Aa. Treatment with mAbs confirmed that the alloimmune response to pcmu-tAa injection depended on CD4, not CD8, T cells. Priming T cells for indirect allorecognition by injection of 15-mer peptides spanning the α1 and α2 domains of Aa failed to stimulate anti-Aa Ab but caused an accelerated Ab response to a PVG.R8 heart and a modest acceleration in graft rejection (median survival time 4 days). These results suggest that both soluble MHC class I and allopeptides prime CD4 T cells by the indirect pathway, but that soluble class I is a more effective immunogen for humoral alloimmunity because its tertiary protein structure provides B cell epitopes. We propose that priming humoral alloimmunity, like CTL priming, requires recognition of intact MHC on donor cells, but essential T cell help can be provided by CD4 T cells recognizing allogeneic class I exclusively by the indirect pathway.

Mechanisms of indirect allorecognition: characterization of MHC class II allopeptide-specific T helper cell clones from animals undergoing acute allograft rejection

BACKGROUND

Recent evidence indicates that T cells primed via the indirect pathway of allorecognition play an important role in allograft rejection, although the effector mechanisms remain unknown. The purpose of this study was to characterize and study the in vivo function of self-restricted MHC allopeptide-specific T-cell clones generated from animals undergoing allograft rejection.

METHODS AND RESULTS

We generated self-restricted class II MHC allopeptide-specific T-cell clones from the spleen and kidney of Lewis (LEW; RT1l) rats undergoing acute rejection of MHC-incompatible Wistar Furth (WF; RT1u) renal allografts. RT1.Du/beta20-44 peptide-specific CD4+ T helper 1 clones from the spleen and kidney of rejecting animals expressed a restricted T cell receptor (TCR) Vbeta repertoire: Vbeta4, 8.2, or 9. In comparison, clones generated from RT1.Dubeta20-44 immunized LEW rats all expressed TCR Vbeta9. The amino acid sequence of RT1.Dl (LEW) and RT1.Du (WF) residues 20-44 differ only at positions 30 and 38. T-cell clones expressing TCR Vbeta9 preferentially proliferated to the peptide fragment RT1.Dubeta20-33. T-cell clones expressing TCR Vbeta4 proliferated weakly to peptide fragments RT1.Dubeta20-33 and 31-44, whereas those expressing TCR Vbeta8.2 proliferated preferentially to the peptide fragment 31-44. Adoptive transfer of T-cell clones expressing TCR Vbeta9 or Vbeta8.2, but not Vbeta4, to naive LEW animals elicited significant delayed-type hypersensitivity responses after challenge with the RT1.Dubeta20-44 peptide or allogeneic WF (RT1u) splenocytes.

CONCLUSION

This is the first report on the cellular, molecular, and functional characterization of self-restricted MHC allopeptide-specific T-cell clones from animals undergoing acute rejection. Our data provide support for a biologically significant role of indirect allorecognition in allograft rejection.

Soluble HLA class I molecules: biological significance and clinical implications

Soluble class I human leukocyte antigens (sHLAs) have been detected in serum, sweat, lymphatic fluid, urine and cerebrospinal fluid. Their biological function has, however, remained a puzzle. The physiological concentration of sHLA varies more than tenfold depending on the phenotype of the individual, and is significantly upregulated in various diseases and during inflammation. This suggests that sHLAs might serve as a marker of pathological changes. Recent experiments have shown that, in vitro, sHLAs can modulate T-cell reactivity and induce cell-activated apoptosis, implicating sHLAs in the induction and maintenance of peripheral tolerance. Therefore, sHLAs have the therapeutic potential to induce tolerance to transplants.

Induction of tolerance toward rat cardiac allografts by treatment with allochimeric class I MHC antigen and FTY720

BACKGROUND

The combination of FTY 720, a novel immunosuppressant, and allochimeric class I MHC proteins bearing donor-type amino acid (aa) epitope substitutions for host-type sequences induces tolerance of Wistar Furth (WF; RT1.Au) heart allografts in ACI (RT1.Aa) recipients.

METHODS

Allochimeric alpha(1h)l58-80-RT1.Aa proteins were produced by substituting the allogeneic nucleotide sequence encoding 10 aa residues unique to the alpha1 helical (alpha1h) region of RT1.Al Lewis (Asp58, Arg62, Glu63, Gln65, Lys66, Gly69, Asn70, Asn73, Ser77, and Asn80) for native RT1.Aa residues. The RT1.Au and the RT1.Al haplotypes share four of these aa (Arg62, Glu63, Gln65, and Gly69). A baculovirus/Spodoptera frugiperda insect cell system was used to express the alpha(1h)l58-80-RT1.Aa proteins.

RESULTS

The addition of a 3-day oral gavage of 0.05 mg/kg/day FTY720 to a single portal vein injection of 10 microg alpha(1h)l58-80-RT1.Aa protein induced permanent acceptance of WF heart allografts in 16 of 26 ACI recipients (>100 days); the alpha(1h)l58-80-RT1.Aa protein alone only modestly prolonged WF heart survival (13.8+/-0.8 days). The same tolerogenic protocol did not prolong the survival of third-party Brown Norway (RT1.An) heart allografts (14.3+/-2.5 days) compared with FTY720 alone (14.0+/-2.3 days; NS). Tolerant ACI recipients bearing primary WF heart allografts for more than 100 days accepted second WF hearts, but promptly rejected third-party Brown Norway heart grafts (9.3+/-1.5 days). The tolerant state was transferred to irradiated ACI rats (400 rad) with either purified T cells (4-10 x 10[7]) or serum (1-2 ml) from tolerant hosts, and was not broken by daily intraperitoneal injections of interleukin-2 (1000 U/day; 7 days).

CONCLUSIONS

The combination of allochimeric protein with FTY720 induces transplantation tolerance, a state that may be associated with the appearance of donor-specific regulatory factors.

Localization of cryptic tolerogenic epitopes in the alpha1-helical region of the RT1.Au alloantigen

BACKGROUND

Transplantation tolerance is induced by perioperative administration of host class I major histocompatibility complex proteins bearing donor-type amino acid (a.a.) epitopes substituted for native residues. Herein we demonstrate that two cryptic tolerogenic a.a. epitopes are localized in the alpha1-helical region of the rat RT1.Au class I major histocompatibility complex alloantigen.

METHODS

Three allochimeric proteins were produced by superimposing the nucleotides encoding donor-type RT1.Au a.a. onto the host RT1.Aa backbone using the polymerase chain reaction-based method of gene splicing with overlap extension. We substituted nucleotide sequences encoding all nine (Arg62, Glu63, Gln65, Gly66, Gly69, His70, Val73, Asn74, and Asn77; alpha1h u62-77-RT1.Aa), the first four (Arg62, Glu63, Gln65, and Gly69; alpha1h u62-69-RT1.Aa), or the last four (His70, Val73, Asn74, and Asn77; alpha1h u70-77-RT1.Aa) alpha1-helical RT1.Au polymorphic a.a. in RT1.Aa cDNA. A baculovirus/Spodoptera frugiperda (Sf9) expression system was harnessed for production of the proteins.

RESULTS

Untreated ACI (RT1a) rats reject Wistar-Furth (WF; RT1u) heart allografts at a mean survival time of 8.9+/-1.0 days. A single portal vein injection of 10 microg of alpha1h u62-77-RT1.Aa protein had no effect on the survival of WF heart allografts (10.5+/-0.6 days) in ACI hosts. Interestingly, portal vein administration of 10 microg of alpha1h u70-77-RT1.Aa induced transplantation tolerance toward WF grafts in four of six untreated ACI recipients (>100 days; P<0.01). In contrast, 10 microg of alpha1h u62-69-RT1.Aa only prolonged the survival of WF heart allografts in ACI hosts (14.0+/-0.8 days; P<0.01). However, when combined with a 7-day course of cyclosporine (4.0 mg/kg; oral gavage), alpha1h u62-69-RT1.Aa induced tolerance toward WF allografts in five of seven ACI recipients (>170 days; P<0.01). Long-term survival of WF grafts was not achieved when a 7-day course of cyclosporine was administered alone (14.3+/-3.0 days) or with 10 microg of alpha1h u62-77-RT1.Aa (14.6+/-0.6 days; NS).

CONCLUSIONS

These findings suggest that the use of allochimeric proteins may provide a novel approach to the induction of tolerance.

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.