Identification of T cell subsets and class I and class II antigen expression in islet grafts and pancreatic islets of diabetic BioBreeding/Worcester rats

The BioBreeding/Worcester (BB/Wor) rat develops a spontaneous disorder that closely resembles human insulin-dependent (Type I) diabetes mellitus. The syndrome is preceded by lymphocytic insulitis that destroys pancreatic beta cells. The morphologic features of the spontaneous insulitis lesions are also observed within islets transplanted beneath the renal capsule of diabetes-prone and diabetic animals. This study reports the results of experiments in which immunohistochemical techniques were used to characterize the phenotype of the infiltrating mononuclear cells and detect the expression of class I and class II MHC antigens in native islets and islet transplants in diabetic and diabetes-prone BB/Wor rats. The infiltrates within native pancreatic islets and islet grafts were comprised predominantly of Ia+ cells (dendritic cells and macrophages) CD4+ cells (helper/inducer lymphocytes and macrophages), CD5+ (pan-T) cells and smaller numbers of CD8+ (cytotoxic/suppressor and NK) cells. Pancreatic and graft insulitis were accompanied by markedly enhanced class I antigen expression on islet and exocrine cells. Class II (Ia) antigens were not detected on normal islet cells, islets undergoing insulitis or on islet transplants subjected to immune attack. In islet grafts stained with polymorphic MAbs that distinguish Ia antigens of donor and host origin, Ia antigen expression was limited to infiltrating dendritic cells and macrophages of host origin. It is concluded that the phenotypes of infiltrating mononuclear cells that comprise the insulitis lesion in spontaneous BB/Wor diabetes, and the inflammatory attack on islets transplanted into diabetic BB/Wor rats are the same, that pancreatic islet and graft insulitis occur in the presence of enhanced class I antigen expression but in the absence of class II antigen expression, and that infiltrating Ia+ cells within islet grafts are exclusively of recipient (BB/Wor) origin and may explain the initiation of immune insulitis within grafts derived from donors of incompatible MHC.     

C. L. Oakley lecture (1987). The pathogenesis of beta cell destruction in type I (insulin-dependent) diabetes mellitus

In a study of pancreases from 75 patients who died at presentation of Type I diabetes there was selective destruction of beta cells associated with islet inflammation (insulitis). According to a recent hypothesis, aberrant expression of Class II major histocompatibility complex (MHC) products on a target cell may allow presentation of organ specific surface antigen(s) to potentially autoreactive T helper lymphocytes and thus lead to autoimmunity. Aberrant expression of Class II MHC was demonstrated immunohistochemically on beta cells in 21 out of 23 patients with recent onset diabetes. No such expression was seen on the other pancreatic endocrine cells. Ninety-four per cent of insulin-containing islets in these patients had marked hyperexpressions of Class I MHC affecting all endocrine cells in these islets. Insulin deficient islets were not thus affected. Both these abnormalities of MHC expression appeared to precede insulitis within a given islet and appeared to be unique to Type I diabetes, being absent in pancreases of patients with Type II diabetes, chronic pancreatitis, cystic fibrosis, graft-versus-host disease and Coxsackie B viral pancreatitis. The development of autoimmunity to beta cells in Type I diabetes may be a 'multistep' process in which abnormalities of MHC expression are crucial events.     

Restriction fragment length polymorphisms in the major histocompatibility complex of the non-obese diabetic mouse

The inbred non-obese diabetic (NOD) mouse is a spontaneous model for insulin-dependent diabetes mellitus (IDDM). As in man and BB rats, IDDM in the NOD mouse has an autoimmune aetiology. The disease is controlled by several genes, one of which, Idd-1, has been mapped to the major histocompatibility complex (MHC) on chromosome 17. However, Idd-1 has not yet been identified. To facilitate the identification of Idd-1 we have further analysed the MHC region for restriction fragment length polymorphisms and we find that the NOD mouse has a distinct haplotype: H-2K1nod Kd A beta nod A alpha d E beta nod TNF-alpha beta. In addition, the NOD mouse shows some similarities with the H-2b haplotype in the Q region, in that either the Q7 or the Q9 gene seems to be like that in the b-haplotype and that the Qa2 antigen is expressed, while other parts of this region are distinct from the b- as well as the d- haplotype. In contrast, the sister strain, the non-obese normal (NON) mouse, derived from the same cataract-prone line of mice as the NOD mouse, has an MHC Class I region indistinguishable from the b-haplotype, but the MHC Class II region is distinct from the NOD mouse as well as the b-, d- and k-haplotype.     

Derivation of non-lymphopenic BB rats with an intercross breeding

Previous studies have suggested that the development of diabetes in the BB rats does not require the expression of T lymphopenia. In order to derive non-lymphopenic diabetic rats and define the relationship between the T cell abnormalities, MHC genotype, and diabetes, we performed a cross between BB/H and diabetes resistant BB/control followed by an intercross of the F1. In the F2, the overall incidence of diabetes and lymphopenia was 30% and 27%, respectively. Lymphopenia was strongly associated with diabetes (p less than 0.001) and was seen in 76% of the diabetic F2's. However, 6 of the diabetic were non-lymphopenic (24%) and 3 of the non-diabetics were lymphopenic (5%). In the non-lymphopenic diabetic animals, all T cell levels were within the normal range, but diabetes occurred at an earlier age than their lymphopenic littermates (p less than 0.001). In contrast to the strong association between the inheritance of lymphopenia and diabetes, no relationship between diabetes and Class I MHC restriction fragment length polymorphisms was found. We conclude: 1) Diabetes and lymphopenia are strongly associated inherited abnormalities in the BB rat and are not associated with Class I RFLP defined genotypes within the RTIu haplotype, 2) Animals in whom diabetes occurs in the absence of lymphopenia can be derived using this breeding approach 3) In our non-lymphopenic rats, diabetes occurred at an earlier age possibly reflecting the restoration of quantitative or qualitative T cell defects found in lymphopenic BB rats.     

Differential expression and regulation of MHC products in the endocrine and exocrine cells of the human pancreas.

Inappropriate expression of HLA Class II (D/DR) molecules has been detected in the target cells of most autoimmune diseases including Type I (insulin-dependent) diabetes. The possibility that this phenomenon is due to the action of lymphocytes or some of their products has been investigated by analysing in vitro the modulation of HLA products in Beta cells. Monolayer cultures from 25 human pancreatic glands were supplemented with alpha-interferon (IFN), beta-IFN or gamma-IFN, interleukin 2 (IL-2) and supernatants from activated lymphocytes. In addition, lectins and a variety of other hormones, biological products and chemicals were tested. Major histocompatibility complex (MHC) expression was assessed by double immunofluorescence technique using monoclonal antibodies to non-polymorphic determinants of Class I and Class II molecules and the pancreatic cells were identified by antibodies to islet hormones and other cytoplasmic antigens. gamma-IFN and lectins produced a parallel enhancement of HLA-A,B,C expression in islet, exocrine/ductal cells and fibroblasts. HLA-D/DR was inducible in all pancreatic cell types, except endocrine islet cells which did not produce Class II molecules in response to any of the stimuli including supernatants from activated lymphocytes. Exocrine/ductal cells from glands of patients with chronic pancreatitis spontaneously expressed Class II products, but islet cells were devoid of any detectable D/DR. These data are consistent with recent observations which have indicated that in the 'diabetic' pancreas inappropriate Class II expression in the Beta cells occurs independently of the presence of lymphocytes infiltrating the islets, and make it necessary to postulate that other factors are responsible for the Class II induction in Beta cells in human Type I diabetes.     

Mouse pancreatic beta cells express MHC class II and stimulate CD4+ T cells to proliferate

Type 1 diabetes results from destruction of pancreatic beta cells by autoreactive T cells. Both CD4⁺ and CD8⁺ T cells have been shown to mediate beta‐cell killing. While CD8⁺ T cells can directly recognize MHC class I on beta cells, the interaction between CD4⁺ T cells and beta cells remains unclear. Genetic association studies have strongly implicated HLA‐DQ alleles in human type 1 diabetes. Here we studied MHC class II expression on beta cells in nonobese diabetic mice that were induced to develop diabetes by diabetogenic CD4⁺ T cells with T‐cell receptors that recognize beta‐cell antigens. Acute infiltration of CD4⁺ T cells in islets occurred with rapid onset of diabetes. Beta cells from islets with immune infiltration expressed MHC class II mRNA and protein. Exposure of beta cells to IFN‐γ increased MHC class II gene expression, and blocking IFN‐γ signaling in beta cells inhibited MHC class II upregulation. IFN‐γ also increased HLA‐DR expression in human islets. MHC class II⁺ beta cells stimulated the proliferation of beta‐cell‐specific CD4⁺ T cells. Our study indicates that MHC class II molecules may play an important role in beta‐cell interaction with CD4⁺ T cells in the development of type 1 diabetes.     

IL-1beta,IFN-gamma and TNF-alpha increase vulnerability of pancreatic beta cells to autoimmune destruction

In the pathogenesis of type-1 diabetes insulin-producing beta-cells are destroyed by cellular autoimmune processes. The locality of beta-cell destruction is the inflamed pancreatic islet. During insulitis cytokines released from islet-infiltrating mononuclear cells affect beta-cells at several levels. We investigated whether cytokine-induced beta-cell destruction is associated with changes in the expression of the surface receptors intercellular adhesion molecule (ICAM)-1 and Fas. Islets from diabetes-prone and congenic diabetes-resistant BB rats were exposed to interleukin (IL)-1beta alone or in combination with interferon (IFN)-gamma plus tumour necrosis factor (TNF)-alpha. Cytokines decreased islet insulin content, suppressed glucose stimulated insulin secretion and generated enhanced amounts of nitric oxide and DNA-strand breaks. While no membrane alterations of IL-1beta treated islets cells were detectable, the cytokine combination caused damage of cell membranes. Independent of diabetes susceptibility IL-1beta treated islet beta-cells expressed a significantly increased amount of ICAM-1 on their surfaces which was not further increased by IFN-gamma+TNF-alpha. However, IL-1beta induced Fas expression was significantly enhanced only on beta-cells from diabetes-prone BB rats. From these results we suggest that IL-1beta mediates the major stimulus for ICAM-1 induction which is possibly a necessary but not sufficient step in the process of beta-cell destruction. Obviously, the additional enhancement of Fas expression on the surface of beta-cells is important for destruction. The combined action of all three cytokines induced the expression of Fas on the beta-cell surface independent of diabetes susceptibility, indicating that such a strong stimulus in vitro may induce processes different from the precise mechanisms of beta-cell destruction in vivo.     

Characterization of pancreatic islet cell infiltrates in NOD mice: effect of cell transfer and transgene expression.

Insulin-dependent diabetes mellitus can be transferred into young irradiated non-obese diabetic (NOD) mice by spleen cells from a diabetic NOD donor. T cells (both L3T4+ and Ly-2+) enter the pancreas 2 weeks following transfer. They are present initially at peri-islet locations but progressively infiltrate the islet with accompanying beta cell destruction. The infiltrate is heterogeneous with respect to V beta usage. Inflammatory macrophages (Mac-1+, F4/80+) can be detected at peri-islet locations at 1 week after transfer and continue to be recruited during the disease process. Their presence at the initiation of disease suggests that their primary function may be autoantigen presentation. Increased expression of major histocompatibility complex (MHC) class I molecules is observed on both endocrine and exocrine tissue in areas of intra-islet infiltration. MHC class II and ICAM-1 expression was restricted to the cells constituting the inflammatory infiltrate. Expression of these molecules was not observed on beta cells implying that presentation of autoantigen by the beta cell itself does not play a role in the beta cell destruction in NOD mice.     

In vitro stimulation by islet antigen facilitates the detectability of beta-cell reactive cells in diabetes-prone BB/OK rats.

It has been supposed that beta-cell destruction in man and animals is due to autoreactive T-cells. We used the [51Cr]-release assay to identify the presence of beta-cell reactive cells in the spleen of diabetes-prone BB/OK rats before and after diabetes manifestation as well as in long-term normoglycaemic rats with a reduced diabetes risk of 3%. Splenic mononuclear cells (MNCs) obtained from diabetes-resistant LEW.1W and the majority of long-term normoglycaemic BB/OK rats (86.4%) showed no reactivity to pancreatic islets in vitro. In contrast, beta-cell reactive cells were identified in dependence on age in 30.4-65.0% of 75-120 days old normoglycaemic rats and in relation to diabetes duration (1 and 20 days) in 75.0% and 16.0% of diabetic BB/OK rats. Islet antigen-specific stimulation of splenic MNCs, that showed no spontaneous islet-directed reactivity, resulted in a concentration-dependent activation of cytolytically reactive cells in BB/OK but not in LEW.1W rats. Splenic MNCs derived from all diabetic, from 82.4% of young normoglycaemic and from 46.2% of long-term normoglycaemic BB/OK rats developed an islet-directed reactivity in vitro. Phenotyping of MNCs showed a significant increase of activated IL2R+ T-lymphocytes in diabetic BB/OK rats, but without any correlation to their cytolytic potential in the [51Cr]-release assay. Despite this fact, IL2R+ cells enriched from the pool of MNCs mediated an enhanced [51Cr]-release from islets, indicating their relevance in the beta-cell destruction. These data suggest, that functional reactivity rather than phenotypic characterization of MNCs is useful to identify the existence of beta-cell reactive cells. Furthermore, for screening diabetes risk in young normoglycaemic BB/OK rats besides the detection of beta-cell reactive cells the occurrence of regulatory cells seems to be decisive.     

Genetic analysis of susceptibility to diabetes mellitus in F2-hybrids between diabetes-prone BB and various MHC-recombinant congenic rat strains.

The occurrence of diabetes mellitus was analysed in F2 hybrids bred from diabetic BB male rats and females of congenic rat strains carrying different major histocompatibility (RT1) haplotypes on the common LEW strain genetic background. Permissiveness for the disease in BB rats is probably determined by class II genes of the RT1 complex, which are also present in normal rats. Class I and class III genes, notably the Hsp70 genes in the class III region, do not appear to be involved. Among the diabetic F2 hybrids, about 90% are shown by DNA analysis to be homozygous for the class II genes of the permissive RT1 haplotype. The segregation patterns are in accord with the action of two independent recessive genes, one of them being RT1-linked.     

Neuere Aspekte zur Pathogenese endokriner Autoimmunerkrankungen des Menschen: Welche Rolle spielt die Expression von HLA Klasse-II-Molekülen durch die endokrine Zielzelle?

Summary The inappropriate expression of HLA Class II molecules by the target cells of endocrine autoimmune diseases is a recent observation that has been intensively studied in thyroid autoimmunity and type I diabetes mellitus. In vitro studies have shown that interferon- can induce Class II expression, either alone, as in thyrocytes, or in combination with other mediators like tumour necrosis factor or lymphotoxin, as in islet cells, pointing to possible mechanisms operating in vivo. Endocrine cells expressing Class II molecules are able to present their autoantigens to helper T cells, thus possibly inducing the autoimmune process. However, until now it is still unclear if the expression of Class II molecules by the target cells is the primary immune phenomenon, which might possibly be triggered by a latent viral infection of the endocrine cell. Alternatively, it might be a secondary response in an ongoing autoimmune process. Particularly data obtained in the diabetic pancreas favour the first possibility, but only progress in our understanding of the role of HLA antigens in immunoregulation will make it possible to interpret the phenomenon properly.

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Abkürzungen MHC Haupthistokompatibilitätskomplex - HLA MHC des Menschen - APC antigenpräsentierende Zelle - PHA Phythämagglutinin - IFN Interferon - IL Interleukin - TNF Tumor Necrosis Faktor - IDDM Diabetes mellitus Typ I - RR relatives Risiko Herrn Prof. Dr. med. W. Kaufmann zum 65. Geburtstag gewidmet     

Immunologic and genetic studies of diabetes in the BB rat

The spontaneous development of diabetes in the Bio-Breeding (BB) rat is an excellent model of human insulin-dependent diabetes mellitus (IDDM). Disease expression is dependent on several genetically determined abnormalities, including specific major histocompatibility complex (MHC) genes. At least one MHC class II locus of the U haplotype is a necessary, but not sufficient, condition for disease expression. The immune system of BB rats is markedly abnormal. There is a striking reduction in the number and function of mature cytotoxic/suppressor T cells, a poor proliferative response to mitogens and in mixed lymphocyte culture, poor interleukin-2 production, and a reduced ability to reject skin allografts. While these immune system abnormalities are closely related to the development of diabetes, the immune recognition and effector mechanisms resulting in islet cell destruction are still poorly understood. The hypothesis that MHC class II induction on pancreatic beta cells serves to target these lymphokines, natural killer (NK) cells, macrophages, etc.) have been implicated in islet cell killing. The incidence of IDDM is reduced by immunosuppressive therapy in both rats and humans, further supporting the role of immune mechanisms in this disease.     

T-cell education in autoimmune diabetes: teachers and students.

Type 1 diabetes mellitus is a classical example of a T-cell-mediated autoimmune disease. Several aberrations in immune regulation have been described in both human diabetes patients and animal models of type 1 diabetes. In this review, we summarize how proposed immune defects might be implicated in the loss of T-cell tolerance towards self in autoimmune diabetes in humans, nonobese diabetic (NOD) mice and Biobreeding (BB) rats. For this purpose, we will discuss the tolerance-inducing mechanisms that an autoreactive T cell should encounter from its genesis to its pathogenic role in the pancreas, in order of appearance. These comprise central tolerance mechanisms (i.e. positive and negative selection in the thymus) and those mechanisms operative in the periphery (i.e. activation-induced cell death and regulatory T cells).     

Pancreas transplantation. An immunohistologic and histopathologic examination of 100 grafts.

The authors examined tissues obtained by biopsy, pancreatectomy, and autopsy from 100 pancreas grafts to determine the cause of dysfunction or failure of the graft. Immunohistologic examination of 42 tissues to determine the mononuclear cell phenotypes and Class I and II antigen expression was performed as well. Technical factors--infections, thrombosis, obstruction--accounted for a large number of graft losses, but immunologic-mediated mechanisms resulted in graft dysfunction and failure as well. Pleomorphic inflammatory infiltrates were present in grafts with acute rejection, as well as Silastic and Prolamine duct-obstructed grafts. Criteria useful in the identification of acute rejection from pancreatitis included a more intense, predominantly mononuclear cell infiltration of transformed lymphocytes in the exocrine pancreas and evidence of vascular rejection--endovasculitis or fibrinoid necrosis. Increased expression and/or induction of Class I and II antigens on pancreatic constituents occurred in grafts with evidence of acute rejection, but also with Silastic and prolamine duct-obstructed pancreatitis. An isletitis occurred in 25% of the grafts. Nine of the 25 grafts (36%) with isletitis also had selective loss of beta cells from the islets. Recurrent diabetes mellitus appeared to have developed in these cases, which accounted for loss of graft function.     

Interactions between B-lymphocytes and type 1 NKT cells in autoimmune diabetes

Type 1 diabetes is one of the most prevalent autoimmune conditions that develops during childhood and has an increasing incidence worldwide. The disease results from the destruction of pancreatic beta cells mediated by autoreactive T-lymphocytes. In order to develop preventive therapies, the cellular mechanisms responsible for the generation and activation of beta cell-specific T-lymphocytes need to be characterized. Recent studies in the NOD mouse model of autoimmune diabetes suggest that the MHC Class II presentation of beta cell-derived antigens by B-lymphocytes could support the development and activity of autoreactive CD4+ T-lymphocytes in this disease. Interestingly, B-lymphocytes are also the most frequent antigen presenting cells expressing the MHC Class I like molecule, CD1d, the restriction molecule responsible for presentation of lipid and glycolipid antigens to Type 1 NKT cells. Splenic marginal zone B-lymphocytes, which express CD1d at particularly high levels, seem poised to signal to Type 1 NKT cells. In contrast to the disease-promoting role of conventional CD4+ T-lymphocytes, several lines of evidence have shown that Type 1 NKT cells are involved in the prevention of Type 1 Diabetes. This review will analyze current knowledge on the roles of B-lymphocytes and Type 1 NKT cells in the onset of Type 1 Diabetes and explore possible outcomes of their interactions in relation to disease.     

Large haplotype-specific differences in inter-genic distances in human MHC shown by pulsed field electrophoresis mapping of healthy and Type 1 diabetic subjects

Type 1 diabetes is associated with extended haplotypes defined by combinations of specific alleles of genes in the MHC. We have used pulsed field gel electrophoresis mapping to examine the gross structure of the Class II region of the MHC and its relationship to susceptibility to Type 1 diabetes. We have studied heterozygous members of a family in which susceptibility to Type 1 diabetes is associated with an A1/B8/DR3 haplotype and resistance with A2/B7/DR2, an unrelated diabetic DR3,4 patient and a healthy DR4,w10 subject and a DR2/Dw2 cell line. Digestion was performed with the enzymes Sst II, Mlu I, and Pvu I and hybridization with 21-hydroxylase, DRA, DQB, DOB and DPA probes. Within the DQ/DR region the DR4- and DR7-bearing haplotypes studied contain insertions of 140-150kb relative to the DR3 haplotypes whilst the DR2 haplotype in the family was smaller than the DR3 haplotypes by 130kb, whilst that in the cell line was smaller by up to 220kb. This cell line, previously thought to be homozygous by consanguinity, was also shown to be heterozygous in the DP region. Although no differences between diabetic and healthy subjects were observed within the family, these differences in long-range structure may be of importance to the etiology of Type 1 diabetes, as well as to the evolution of the MHC.     

Class II MHC antigen induction on rat insulinoma (RINm5F) and colon carcinoma (TS) cells by co-culture with diabetic and normal xenogenic lymphocytes

Two MHC Class II-negative rat epithelial cell lines (RINm5F beta-cells and TS colic cells) were co-cultured with xenogenic lymphocytes from Type I diabetic patients or from low-dose streptozotocin (SZ) diabetic mice. MHC Class II antigens (Ag) were easily induced on both cell lines in such co-culture conditions, representing an experimental approach to insulitis. Our data indicate that: (1) lymphocytes from diabetic patients or from SZ mice were more efficient than lymphocytes from healthy controls in inducing Class II Ag on RIN cells. Lymphocytes from patients with autoimmune thyroid diseases were also more efficient than control lymphocytes, indicating that the ability to induce Class II may be related to the activation of lymphocytes rather than being diabetes-specific. (2) Rat colon carcinoma cells (TS) were also induced to express high levels of Class II Ag upon co-culture with SZ or control mouse lymphocytes. (3) Class II+ RIN cells were observed after 24 h of co-culture; their number increased after 48 and 72 h. The number of class II+ RIN increased proportionally to the number of lymphocytes in the culture. (4) Induction of Class II Ag was obtained by cell-free supernatants of mouse lymphocytes/RIN co-cultures and was inhibited by cyclosporine A, suggesting that Class II induction in this model is mediated by lymphokines. (5) Depletion experiments indicate that both monocytes and lymphocytes play a role in this Class II induction.     

Non-tolerance and differential susceptibility to diabetes in transgenic mice expressing major histocompatibility class II genes on pancreatic beta cells

In insulin-dependent diabetes mellitus aberrant expression of major histocompatibility complex (MHC) class II antigens might induce autoimmune destruction of insulin-producing pancreatic beta cells. Here we demonstrate that already the expression of single MHC class II chains (E alpha k and E beta b) is sufficient to cause diabetes without affecting beta cell morphology and cell numbers. Our transgenes interfere at least in two points of insulin production leading to a severely diabetic phenotype. In one case E beta b expression led to a 10-30-fold decrease of mouse insulin mRNA. In another case E alpha k expression reduced insulin secretion to background levels. In addition, we also found a patchy distribution of both insulin and E alpha k expression, indicating heterogeneity of the beta cell population, without the concomitant development of diabetes. Although the transgenic E alpha k E beta b MHC class II molecules were expressed on the surface of pancreatic beta cells, the transgenic mice did not prove to be tolerant for I-E antigen. Autoimmune reactions remained absent showing that aberrant MHC class II expression on pancreatic beta cells alone is not sufficient for the development of autoimmune diabetes in mice.     

Pancreatic islets activate portal vein endothelial cells in vitro

This study assessed the active role of the portal vein endothelium in the functional loss of pancreatic islet (PI) grafts, considered in the context of PI transplantation for treatment of type I diabetes mellitus. We hypothesized that PI engraftment may be jeopardized by portal vein endothelial cell-induced activation of host T cells. We designed an in vitro system using portal vein endothelial cells (PVEC) from Lewis (Lew) rats and PI from Brown-Norway (BN) and Lew rats. PI were co-cultured with Lew PVEC for three days. The PI were removed and trypsinized PVEC were divided into three groups: (A) PVEC not exposed to PI; (B) PVEC exposed to syngeneic PI; and (C) PVEC exposed to allogeneic PI. The groups were analyzed by flow cytometry for ICAM-1 and MHC Class I and Class II molecules. Functional assays of lymphocytes (ie, lymphocyte proliferation assay, 51Cr release assay, and cytokine release assay) were also performed. We observed MHC Class I and ICAM-1 upregulation on PVEC after PI contact. MHC Class II molecule was not upregulated on PVEC after PI exposure. IL-6 production was increased non-specifically following PI coculture with PVEC. TNF-a was increased only after allogeneic PI-PVEC coculture. PVEC exposed to either allogeneic or syngeneic PI could not stimulate na?ve splenocyte proliferation or cytotoxicity. We conclude that PVEC allo-PI interaction results in increased ICAM-1 and MHC Class I expression on the PVEC. Neither lymphocyte proliferation nor cytotoxicity could be enhanced in response to enhanced MHC Class I and ICAM-1 expression, which was associated instead with non-specific inflammatory cytokine release.