Cell subsets responding to purified hepatocytes and evidence of indirect recognition of hepatocyte major histocompatibility complex class I antigen. I. The role of L3T4+ T cells in the development of allospecific cytotoxicity in hepatocyte-sponge matrix allografts.

The purpose of this study was to determine the role of L3T4+, Ly2- T cells in the development of allospecific cytolytic T cells in response to purified allogeneic MHC class I+, class II- hepatocytes in vivo in hepatocyte-sponge matrix allografts (HC-SMA). In previous studies we have shown that 99% pure murine hepatocytes stimulate the development of allospecific cytolytic T cells in vitro in mixed lymphocyte-hepatocyte culture (MLHC) and in vivo in HC-SMA. Furthermore, depletion of L3T4+, Ly2- T cells from responder splenocytes inhibits the development of allo-CTLs in response to purified hepatocytes in mixed lymphocyte-hepatocyte culture. Here, using an anti-L3T4 monoclonal antibody, we tested the effect of in vivo immunodepletion of L3T4+, Ly2- T cells on the subsequent development of allo-CTLs in HC-SMA. Sponge cells were harvested on day 4 and day 12 after grafting from control and treated groups and phenotypically analyzed by FACS and immunofluorescent labelling. Splenocytes from the same animals were similarly analyzed to assess for completeness of immunodepletion. Allospecific cytotoxicity was assessed on day 12 after grafting. We found that immunotherapy with anti-L3T4 mAb was effective in depleting L3T4+, Ly2- T cells from the spleen; however, a similar number of L3T4+ cells was isolated from the sponge between control and treated groups. Furthermore, the development of allo-CTLs in response to hepatocytes in HC-SMA was completely abrogated by both local and systemic immunotherapy with anti-L3T4 mAb. We conclude from these and previous data that host or responder L3T4+, Ly2- T cells and responder accessory cells in MLHC or host macrophages in HC-SMA may participate in "indirect" recognition of hepatocyte class I antigen both in vitro and in vivo.     

Comparison of in vivo and in vitro immune response to purified hepatocytes

We have previously reported that freshly isolated percoll-purified hepatocytes are MHC class I+, Class II- and stimulate allospecific cytotoxicity in mixed lymphocyte hepatocyte culture. In this report we determined the immunogenicity of purified hepatocytes in vivo using a modification of the sponge matrix allograft model. We found that hepatocytes were immunogenic in vivo because they stimulated the development of cytolytic effectors in allogeneic but not syngeneic hepatocyte sponge matrix allografts. These cytolytic effectors were not macrophages (because cytotoxicity was intact after nylon wool depletion of the bulk sponge effectors) but rather were Ly2+, L3T4- T cells. Cytolytic effectors in both MLHC and hepatocyte sponge matrix allografts demonstrated marked specificity for allogeneic MHC class I antigen of stimulator and donor hepatocytes, respectively. Allospecific cytolytic T cells developed in both MLHC and hepatocyte sponge matrix allografts across an isolated MHC class I genetic disparity but not across an isolated class II genetic disparity. Finally, sequential phenotypic analysis of host cells infiltrating allogeneic hepatocyte sponge matrix allografts demonstrated the presence of macrophages, Ly2+, L3T4- and Ly2-, L3T4+ T cells.     

Afferent and efferent pathways in T cell responses to MHC class I+, II-hepatocytes

We have previously reported that purified hepatocytes stimulate significant in vitro allospecific cytotoxicity when cocultured with naive responder splenocytes in the mixed lymphocyte hepatocyte culture (MLHC). In this report we examined the expression of MHC antigens on the surface of hepatocytes, the phenotypic lymphocyte subset(s) that respond(s) to allogeneic hepatocytes, and the phenotype of allospecific cytolytic effectors generated in MLHC. Hepatocytes expressed MHC class I but not MHC class II antigens by immunofluorescent microscopy and fluorescence activated cell sorting. The lack of MHC class II on the surface of hepatocytes was also indirectly supported by the inability of hepatocytes to stimulate proliferation of a class II-directed allospecific helper T cell clone. The generation of allospecific cytotoxicity in MLHC required the participation of L3T4+, Ly2- T cells and L3T4-, Ly2+ T cells in the naive responder splenocyte population since depletion of these subsets with mAb and complement abrogated the development of allo-CTLs. Furthermore, adherent accessory cells in the naive responder splenocyte population appeared to play a role in the generation of allospecific cytotoxicity in MLHC since depletion of this population by plastic adherence and passage through a Sephadex G10 column resulted in significantly reduced allospecific cytotoxicity. Depletion of day 5 allosensitized cells of Ly2+ but not L3T4+ T cells by mAb and complement eliminated allospecific cytotoxicity--indicating that cytolytic effectors generated in MLHC appear to be L3T4-, Ly2+ T cells.     

Cell subsets responding to purified hepatocytes and evidence of indirect recognition of hepatocyte major histocompatibility complex class I antigen. II. In vitro-generated "memory" cells to class I+ class II- hepatocytes.

Purified hepatocytes stimulate the development of L3T4-, Ly2+ allospecific cytolytic T cells from naive splenocytes after 5 days in primary mixed lymphocyte-hepatocyte culture (MLHC). Previous studies indicate that the immunogenicity of purified hepatocytes relates to the expression of MHC class I antigen. The purpose of the following experiments was to identify the cell subsets that specifically recognize hepatocyte MHC class I antigen. We employed primed lymphocyte testing (PLT) in order to test for a "second set" response. Cells from primary MLHC reverted to a functionally quiescent state when they were grown in culture for an additional 7-9 days. The cells were then tested for cytotoxicity or rechallenged with allogeneic, syngeneic, or "third party" hepatocytes and tested for proliferation. Allocytotoxicity was low on day 12 in MLHC, but the sensitized cell population demonstrated peak proliferation in response to allogeneic hepatocytes 48 hr after restimulation. When bulk PLT cells were immunodepleted, both L3T4+, Ly2- and L3T4-, Ly2+ T cell subsets demonstrated a "second set" response to allogeneic hepatocytes consistent with specific recognition of and retention of "memory" for hepatocyte MHC class I alloantigen.     

Comparative phenotype and immunogenicity of freshly isolated and immortalized rat hepatocytes

Immortalized hepatocytes are an attractive cell source for hepatocyte transplantation and gene transfer. We compared the phenotype and immunogenicity of freshly isolated (FIH) and immortalized (IMH) rat hepatocytes. Effect of culture and proinflammatory cytokines (TNF-alpha, IFN-gamma) was studied on phenotype. FIH were isolated by collagenase digestion. Two SV40 immortalized hepatocyte cell lines were tested (RH1 and P9). Immunophenotyping was performed by FACS analysis using anti-rat-specific antibodies. Immunogenicity was evaluated by a mixed lymphocyte hepatocyte reaction (MLHR). FIH suspension was an almost homogeneous parenchymal cell population with few (1-2%) CD8+ cells. FIH showed a positive staining for ICAM-1 (20-35%) and for Class I (RT1A, 30-60%) but no staining for Class II (RT1B). After 48 h of culture, the already ICAM-1-positive cells were more strongly stained and additionally 3.6% of the cells (possibly endothelial cells) were Class II positive. IMH showed a consistent expression of Class I (93-97%) and ICAM-1 (95-97%) but no expression of Class II. Culture of IMH for 48 h had no effect on Class II expression but increased ICAM-1 expression. Addition of TNF-alpha at 1000 UI/ml to cultures of FIH or IMH increased Class I and ICAM-1 expression whereas IFN-gamma (50 or 1000 UI/ml) had no evident effect. Hepatocyte immunogenicity, assessed in MLHR and appreciated by the stimulation index (SI) test/SI syngeneic control, was similar for IMH (RH1: 2.68+/-0.89; P9: 2.37+/-0.78) and FIH (2.52+/-0.18). In conclusion, despite some quantitative immunophenotypic differences, FIH and IMH induced the same proliferation rate of allogeneic T lymphocytes. Thus, immortalized hepatocytes may constitute an appropriate cellular model to study the prevention of hepatocyte rejection by gene transfer.     

Modulation of hepatocyte protein synthesis by endotoxin-activated Kupffer cells. III. Evidence for the role of a monokine similar to but not identical with interleukin-1.

The authors previously reported that unstimulated peritoneal macrophages and LPS stimulated Kupffer cell-rich nonparenchymal liver cells (NPC) can inhibit protein synthesis in cultured rat hepatocytes. Hepatocyte function was similarly altered by supernatants from LPS-triggered NPC. Secretory products of macrophages and Kupffer cells (monokines) are possible mediators in this model of cell-mediated modulation of hepatocyte function. In this article, supernatants from NPC capable of altering hepatocyte protein synthesis were found to contain significant amounts of one monokine, interleukin-1 (IL-1). The kinetics of the generation of the ability to inhibit protein synthesis and the appearance of IL-1 activity were roughly parallel for the first 24 hours. Exposure of hepatocytes to NPC supernatant and commercially available highly purified IL-1 resulted in similar response patterns with regard to onset of inhibition and progression of suppression after removal. Certain discrepancies cast doubt, however, on the likelihood that IL-1 is the mediator in this model of cell-mediated inhibition of hepatocyte protein synthesis. Commercial human IL-1 preparations did not always suppress protein synthesis in cultured rat hepatocytes. Furthermore, IL-1 activity was stable for several days but hepatocyte inhibition was lost. Unstimulated peritoneal macrophage supernatants containing IL-1 activity could not inhibit protein synthesis in hepatocytes. The evidence supports the idea that appropriately stimulated cells of monocyte-macrophage lineage (including Kupffer cells that lie in direct apposition to hepatocytes) could mediate hepatocyte malfunction by means of secreted monokines similar to, but not necessarily identical to, IL-1.     

Identification, characterization, and quantitation of soluble HLA antigens in the circulation and peritoneal dialysate of renal patients

Human lymphocyte antigen (HLA) class I and class II antigens and beta 2 microglobulin (B2M) were identified in peritoneal dialysate (PD) and serum from patients with end-stage renal disease (ESRD) using monoclonal antibodies in an enzyme-linked immunoassay. The HLA class I and class II antigens each exhibited approximate molecular weights of 50,000 to 60,000 daltons by chromatography on Sepharose CL 6B. Class I antigens in serum and PD fluid were associated with B2M. Free B2M (Mr 11,500) also was detected in both sera and PD fluids. Unlike class I antigens, class II antigens were not found to have attached B2M. Class I and class II antigens eluted from 2-diethylaminoethanol ion exchange gradient columns at 0.07 mol/L (molar) phosphate buffer pH 7.2 and migrated with alpha 2-beta 1 mobility in agarose electrophoresis. Class I antigens were purified from ESRD patients' PD fluid by solid-phase immunoaffinity chromatography. Enzyme-linked immunoassay demonstrated that this purified protein was composed of a class I heavy chain and B2M. Class I allospecificity was confirmed by neutralization on known HLA typing antisera in a microcytotoxicity assay. Soluble HLA class I antigen preparations specifically inhibited blast transformation of responder lymphocytes in mixed lymphocyte culture reactions. Inhibition was dose dependent and ranged from 0% to 95%. The presence of soluble HLA antigens in body fluids may play an important part in the immunologic tolerance to self. This study demonstrates a ready source of large quantities of soluble HLA for detailed analysis.     

Evidence for direct and indirect pathways in the generation of the alloimmune response against pancreatic islets.

The role of the direct and indirect pathways of alloantigen presentation in the generation of the alloimmune response was dissected using the murine mixed lymphocyte-islet coculture system (MLIC). Stimulator DBA/2J (H-2d) pancreatic islet populations consisted of whole islets (MHC class I+, II+) or FACS-purified beta cells (MHC class I+, II-). Responding C57Bl/6 (H-2b) splenocyte populations were either: (1) untreated; (2) depleted of helper T cells with anti-L3T4 monoclonal antibody plus complement; (3) depleted of cytotoxic T lymphocytes with anti-Lyt2 mAb plus complement; or (4) depleted of antigen-presenting cells by passage through a Sephadex G-10 column. Whole islets were capable of stimulating a significant C57Bl/6 anti-DBA cytotoxic T cell response if the responding population was untreated or treated with complement alone. Depletion of responding splenocytes with either anti-Lyt2 or anti-L3T4 mAb plus complement abrogated the generation of allospecific CTL. If the responding splenocyte population was depleted of APCs, the allo-CTL response against whole islets was decreased, but still significant. If, however, the stimulator population consisted of FACS-purified DBA 2J beta cells, APC-depleted C57Bl 6 splenocytes were incapable of generating any CTL response. Adding responder type (C57Bl/6) APCs back to the microwells restored the capacity for both whole islets and purified beta cells to stimulate a strong allo-CTL response. These data demonstrate that both indirect and direct pathways of alloantigen presentation function in the MLIC.     

Direct activation of human responder T cells by porcine stimulator cells leads to T cell proliferation and cytotoxic T cell development

Abstract: Functional activities of highly purified T human responder lymphocytes reactive against porcine stimulator cells were studied to evaluate whether porcine stimulator cells can directly activate a xenospecific cellular immune response. Mixed lymphocyte culture (MLC) tests revealed that CD4+ human responder cells proliferate when stimulated in vitro with porcine cells, a reaction similar to that of alloresponses regarding magnitude and tempo. A direct pathway of activation was verified by the requirement for adherent porcine stimulator cells and the partial blocking by monoclonal antibodies against porcine major histocompatibility complex (MHC) class II antigens. An analysis of proliferative CD4+, CD3+, CD16-, and 56- human T cell clones revealed that some clones were seemingly recognizing allele-specific determinants, whereas others could be restimulated by a wide range of porcine stimulator cells. Cytotoxic T cells (CTLs) were generated following direct recognition of pig cell ligands by human T cells in the absence of autologous antigen-presenting cells (APCs). Although the identification of target antigen(s) on the pig cell recognized by the CTL warrants some discussion, the pattern of killing exhibited by the CTLs indicates the recognition of porcine polymorphic determinant(s). The implications of these findings for cellular reactivity against porcine transplants are discussed.     

Graft rejection in a congenic panel of rats with defined immune response genes for class I antigens. II. Quantitative aspects of Ir gene function in a full-haplotype mismatch

Previous studies have shown that the Ir-gene-controlled rejection of rl tissues by c/u responder and non-rejection by c low responders does not extend to tissues expressing a full a haplotype mismatch. However, antibody responses and liver graft rejection are both defective in low responders, even across a full haplotype barrier. We have therefore used a titrated adoptive transfer assay to search for quantitative differences in the responsiveness of c and c/u animals to a organ grafts. We first established that a heart graft rejection could be ablated in both recipient strains with whole-body irradiation and could be restored with syngeneic cells. Titration of restorative cells revealed that 5 times as many c cells were required to restore graft rejection in c recipients as c/u cells were required in c/u recipients. Use of cells from primed donors showed that in both c/u and c animals these cells had undergone about a 5-fold increase in potency, showing that there was no failure of proliferation and differentiation in the low responder after contact with antigens. Cross-transfer experiments were done to attempt to localize the defect in low-responder animals either to a failure of low-responder antigen-presenting cells (APC) to trigger a response or a defect in the responsiveness of alloreactive cells toward the a antigens. In these experiments c cells were obtained from radiation chimeras of the c----c/u type. These cells were used to restore graft rejection in c/u irradiated recipients. Similar experiments employing c/u cells obtained from c/u----c chimeras and given to irradiated c recipients were also done. These showed that c cells from chimeras were marginally less potent than c/u cells from chimeras. In contrast when cross-transfer of c/u cells to c animals bearing a nonrejected rl heart was done, no rejection was seen even when antigen presenting cells were cotransferred. The conclusions from this series of experiments were that quantitatively small defects were present in both repertoire and antigen presentation, and that these quantitative defects in aggregate were probably sufficient to explain the documented low responsiveness of c animals to the a haplotype. The failure of high-responder c/u cells to secure rejection of rl tissues in the low-responder c environment suggests that presentation of isolated class I differences in host APCs is mandatory for rejection to occur and is highly defective in the c animal.     

Purified donor T cells alone activate transplantation immunity to the male antigen but induce tolerance in combination with Mac-1+ donor cells.

BACKGROUND: In most experimental systems examined, "professional" antigen-presenting cells (APCs), such as dendritic cells, have been found to activate T cells, whereas "nonprofessional" antigen-bearing cells (nonAPC) may induce tolerance. Some recent studies have suggested that nonAPCs may under certain conditions prime a T-cell immune response. We have attempted to separate the roles of transplanted T cells and monocytic/dendritic cells in activating or tolerizing antigen-specific T cells in vivo, by examining the consequences of parenteral exposure to male antigen in anti-male TCR transgenic female mice. METHODS: Qualitative and quantitative changes in the large population of male-reactive transgenic T cells to various male donor cell populations in transgenic female mice were followed after injections of highly purified male lymphoid cells. Changes in male-reactive T cells with time and the long-term outcome of male skin grafts were measured. RESULTS: When a nonAPC population consisting of highly purified male T cells alone was injected intravenously into H-Y antigen-specific TCR transgenic female mice, the number of host transgenic T cells was sustainably increased, and male graft rejection was accelerated. Injection of a combination of purified T cells and purified Mac-l+ cells induced massive and permanent deletion of the host male-reactive T-cell population and permanent graft tolerance. Mac-l+ cells alone gave no appreciable change in responsive T cells or graft rejection times. CONCLUSIONS: The data indicate that highly purified T cells engrafted alone induce rapid sensitization toward the male antigen. They also show that both male donor T cells and a population of male monocytic/ dendritic cells are required to induce peripheral tolerance toward this antigen and that this tolerance is related to permanent peripheral deletion of male-reactive T cells.     

Further characterization of Kupffer cell/macrophage-mediated alterations in hepatocyte protein synthesis

Alterations in hepatic function are seen in sepsis or multiple-system organ failure. We have hypothesized that Kupffer cells (KCs) within the liver alter the function of contiguous hepatocytes after exposure to septic stimuli. Using an in vitro coculture system, we have found that lipopolysaccharide (LPS) induced a 40% to 60% decrease in cocultured hepatocyte protein synthesis but had no effect on hepatocytes alone. Coculture in the absence of LPS resulted in enhanced hepatocyte protein synthesis proportional to the number of KCs or macrophages (M0s). Conditioned medium (CM) from LPS-triggered coculture or KC alone decreased protein synthesis of hepatocytes whereas CM from hepatocytes alone had no effect. Gel filtration of active M0-CM showing maximal hepatocyte inhibitory activity was present in fractions between 15,000 and 30,000 daltons. This inhibitory activity was inactivated by exposure to 65 degrees C for 30 minutes. Although CM from untriggered M0 did not inhibit hepatocyte protein synthesis, lysates from both LPS-triggered and control M0 were inhibitory. These results show that M0s/KCs exposed to septic stimuli decrease hepatocyte protein synthesis via heat labile, soluble mediator(s) that may already be synthesized within untriggered cells. We hypothesize that soluble M0/KC mediators normally modulate hepatocyte function and that this normal homeostatic control is profoundly altered during sepsis.     

Pretransplant sensitization with major histocompatibility complex class I+ class II- hepatocytes leads to accelerated skin graft rejection.

The immunogenicity of major histocompatibility complex (MHC) class I+ class II- hepatocytes is controversial. We studied the effect of pretransplant donor-specific sensitization with either purified hepatocytes (HC) or splenocytes (Spl) on subsequent skin allograft survival. Five million Percoll-purified DBA HC or 10 x 10(6) DBA Spl were injected into C57BL/6 recipients either intraperitoneally (ip) or into a sponge matrix allograft. Twelve days later, sensitized mice received a DBA skin graft. On the same day, allogeneic (DBA) and syngeneic (BL/6) skin grafts were placed on naive BL/6 mice. In naive BL/6 mice, allogeneic skin graft survival was 7.8 +/- 0.5 days (n = 4), and syngeneic survival was indefinite (n = 5). Skin graft survival (mean +/- SD in days) in recipients sensitized with hepatocytes ip was 6.0 +/- 1.2 days (n = 5) compared with 5.6 +/- 0.5 days in recipients sensitized with splenocytes ip. Similarly, graft survival in recipients that received hepatocytes into a sponge matrix allograft was 5.67 +/- 1 days (n = 6) compared with 5.2 +/- 1.1 days (n = 8) in those that received splenocytes into the sponge. There was no difference in graft survival between mice sensitized with HC vs Spl, nor between mice injected ip vs with the sponge. All sensitized mice experienced accelerated graft rejection compared with naive controls (P less than 0.000). These results demonstrate that purified MHC class I+, class II- murine HCs are immunogenic in vivo. Sensitization with donor-specific HCs led to accelerated rejection of subsequent skin grafts, similar to the accelerated rejection seen after sensitization with MHC class I+ and class II+ splenocytes.     

Hepatocyte transplantation for the low-density lipoprotein receptor-deficient state. A study in the Watanabe rabbit

The Watanabe heritable hyperlipidemic (WHHL) rabbit reproduces human familial hypercholesterolemia due to a congenital low-density lipoprotein receptor deficiency and is characterized by elevated serum LDL cholesterol levels and early atherosclerosis. We attempted to transplant normal allogeneic hepatocytes into WHHL rabbits without chronic immunosuppression to cure the LDL receptor-deficient state. Livers from normal New Zealand White (NZW) rabbits were digested by intraportal perfusion of collagenase solution. Pure hepatocytes (PH) were obtained by Percoll gradient separation and nonparenchymal (NP) liver cells by pronase digestion. PH and NP were incubated with fluorescein isothiocyanate-monoclonal anti-rabbit class I, anti-class II, and anti-T cell antibodies and subjected to flow cytometry analysis. PH and NP were also used as stimulators in one way mixed lymphocyte-hepatocyte cultures (MLHC), before and after ultraviolet B light (UVB) exposure. Intraportal and intrasplenic injection of allogeneic PH were also performed in homozygous WHHL rabbits. PH were attached to collagen-coated dextran microcarriers (mc-PH) for intraperitoneal injection. Recipient control and transplanted WHHL rabbits received a single dose of cyclosporine subcutaneously (10 mg/kg/s.c.) at the time of transplantation. PH were mainly class I-positive (77.6%) and class II-negative (5.9%), while 31.5% of NP cells were class II-positive. In MLHC, PH did not stimulate proliferation, (stimulation index: 0.97 +/- 0.21), unlike NP (SI: 23.7). This latter response was abrogated by prior exposure of NP to UVB light. Intraportal injection of PH (n = 4) reduced serum LDL cholesterol to 60% of baseline, an effect lasting 2-3 weeks, and dose-dependent. Intraperitoneal mc-PH, 4 x 10(8) (n = 4), reduced serum LDL cholesterol levels to 45% of baseline more than 4 weeks posttransplant (P = 0.04). We conclude that transplantation of normal allogeneic NZW rabbit mc-PH reduces serum LDL cholesterol levels in homozygous WHHL rabbits without chronic immunosuppression. Longitudinal studies will establish if less atherosclerosis develops in mc-PH WHHL recipients than sham controls.     

Defective HLA Class I Expression and Patterns of Lymphocyte Infiltration in Chordoma Tumors

BackgroundThere are no effective systemic therapies for chordoma. The recent successes of immunotherapeutic strategies in other cancers have resulted in a resurgence of interest in using immunotherapy in chordoma. These approaches rely on a functional interaction between the host’s immune system and the expression of tumor peptides via the human leukocyte antigen (HLA) Class I antigen. It is not known whether chordoma cells express the HLA Class I antigen.Questions/purposes(1) Do chordoma tumors exhibit defects in HLA Class I antigen expression? (2) What is the pattern of lymphocyte infiltration in chordoma tumors?MethodsPatients with chordoma treated at Massachusetts General Hospital between 1989 and 2009 were identified with permission from the institutional review board. Of the 75 patients who were identified, 24 human chordoma tumors were selected from 24 distinct patients based on tissue availability. Histology slides from these 24 formalin-fixed paraffin-embedded chordoma tissue samples were deparaffinized using xylene and ethanol and underwent heat-induced antigen retrieval in a citrate buffer. Samples were incubated with monoclonal antibodies directed against HLA Class I antigen processing machinery components. Antibody binding was detected via immunohistochemical staining. Staining intensity (negative, weakly positive, strongly positive) was assessed semiquantitatively and the percentage of chordoma cells stained for HLA Class I antigen subunits was assessed quantitatively. Hematoxylin and eosin-stained histology slides from the same 24 chordoma samples were assessed qualitatively for the presence of tumor-infiltrating lymphocytes and histologic location of these lymphocytes. Immunohistochemical staining with monoclonal antibodies directed against CD4 and CD8 was performed in a quantitative manner to identify the lymphocyte subtype present in chordoma tumors. All results were scored independently by two investigators and were confirmed by a senior bone and soft tissue pathologist.ResultsSeven of 24 chordoma samples exhibited no staining by the anti-HLA-A heavy chain monoclonal antibody HC-A2, two had weak staining intensity, and eight had a heterogeneous staining pattern, with fewer than 60% of chordoma cells exhibiting positive staining results. Four of 24 samples tested were not stained by the anti-HLA-B/C heavy chain monoclonal antibody HC-10, five had weak staining intensity, and 11 displayed a heterogeneous staining pattern. For the anti-β-2-microglobulin monoclonal antibody NAMB-1, staining was detected in all samples, but 11 had weak staining intensity and four displayed a heterogeneous staining pattern. Twenty-one of 24 samples tested had decreased expression in at least one subunit of HLA Class I antigens. No tumors were negative for all three subunits. Lymphocytic infiltration was found in 21 of 24 samples. Lymphocytes were primarily found in the fibrous septae between chordoma lobules but also within the tumor lobules and within the fibrous septae and tumor lobules. Twenty-one of 24 tumors had CD4+ T cells and 11 had CD8+ T cells.ConclusionIn chordoma tissue samples, HLA Class I antigen defects commonly were present, suggesting a mechanism for escape from host immunosurveillance. Additionally, nearly half of the tested samples had cytotoxic CD8+ T cells present in chordoma tumors, suggesting that the host may be capable of mounting an immune response against chordoma tumors. The resulting selective pressure imposed on chordoma tumors may lead to the outgrowth of chordoma cell subpopulations that can evade the host’s immune system.Clinical RelevanceThese findings have implications in the design of immunotherapeutic strategies for chordoma treatment. T cell recognition of tumor cells requires HLA Class I antigen expression on the targeted tumor cells. Defects in HLA Class I expression may play a role in the clinical course of chordoma and may account for the limited or lack of efficacy of T cell–based immunity triggered by vaccines and/or checkpoint inhibitors.     

Expression and modulation of major histocompatibility antigens on murine primary brain tumor in vitro

Lysis of tumor cells by activated cytotoxic lymphocytes requires their recognition of antigens associated with major histocompatibility complex molecules. The authors studied the constitutive expression of Class I and Class II major histocompatibility complex antigens on mouse brain-tumor cells and the capacity of different cytokines and cytokine combinations to alter this expression in vitro. Cells from the murine glioma 26 (GL26), glioma 261 (GL261), and ependymoblastoma A (EpA) cell lines were established in monolayer culture and treated for 48 hours with either alpha interferon, gamma interferon, tumor necrosis factor alpha, tumor necrosis factor alpha plus gamma interferon, or interleukin-2. They were then analyzed by flow cytometry for baseline and cytokine-altered major histocompatibility complex expression. All cell lines had a similar constitutive major histocompatibility complex pattern with low Class I antigen expression and no detectable Class II antigen expression. Alpha interferon substantially induced and up-regulated Class I antigen expression, but had no effect on Class II antigen expression. Gamma interferon also stimulated up-regulation of Class I antigen expression, generally doubling the anti-Class I antigen fluorescence of treated cells. Its effect on Class II antigen expression was more extensive. In the GL26 and GL261 cell lines the expression of Class II antigen determinants increased to 12 x and 14 x control values and as many as 75% of cells that had no detectable constitutive expression of Class II antigen expressed this antigen after priming with gamma interferon. The addition of tumor necrosis factor alpha to gamma interferon further increased Class II antigen expression on EpA tumor cells only. Interleukin-2 and tumor necrosis factor alpha alone had no effect on Class I or Class II antigen expression of any cell lines. It is concluded that Class I and Class II antigen expression in mouse glioma cell lines is induced and enhanced after treatment with certain cytokines in vitro. Use of these cell lines to create in situ primary brain tumors in C57BL/6 mice should provide an excellent animal system to study major histocompatibility complex modulation in brain tumor cells and to examine the potential impact of major histocompatibility complex up-regulation on the response of brain tumors to immunotherapy.     

Lymphocytes capable of mediating delayed-type hypersensitivity reactions accumulate within sponge matrix allografts

The rejection of sponge matrix allografts across H-2 barriers has generally been found to contain specifically sensitized cytotoxic T cells to donor alloantigen. There is one exception: sponge matrix allografts that differ only with respect to class II alloantigens do not contain specifically sensitized cytotoxic T cells. We therefore investigated the capacity of infiltrating cells removed from sponge matrix allografts to generate delayed hypersensitivity reactions after exposure to fresh alloantigen in a footpad assay. Cells infiltrating class I and II allografts were equally capable of eliciting delayed footpad reactions when injected with specific donor alloantigen into the footpads of naive responder strain mice. Allosensitized T-lymphocyte clones of helper or cytotoxic type were also capable of initiating delayed-type hypersensitivity (DTH) reactions in vivo. We conclude that rejecting allografts across class I or II alloantigenic barriers are infiltrated by cells capable of effecting DTH reactions, in addition to their capacity to exert specific helper or specific cytotoxic reactions. The results also support that both helper and cytotoxic T cells can participate in allospecific DTH reactions.     

Enrichment of hepatocytes differentiated from mouse embryonic stem cells as a transplantable source

BACKGROUND: We previously reported that hepatocytes can be differentiated from embryonic stem (ES) cells by way of embryoid body (EB) formation and are transplantable into the mouse liver. However, the transplantation of EB-derived cells frequently resulted in teratoma formation in the recipient liver. In the present study, we eliminated the tumorigenic cells from EB outgrowths and examined the effects of enriched ES-cell-derived hepatocyte transplantation into an injured liver. METHODS: On day 15 in culture, the EBs were partially disaggregated and subcultured. Hepatocytes in the subcultured cells were examined by the expression of hepatocyte markers. Undifferentiated cells contaminating in the EB-derived cells were eliminated by Percoll discontinuous gradient centrifugation. Furthermore, undifferentiated cells, endothelial cells, and macrophages were eliminated by magnetic cell sorting using platelet/endothelial cell adhesion molecule (PECAM)-1 and Mac-1 antibodies. These enriched ES-cell-derived hepatocytes were then transplanted into the injured mouse liver. RESULTS: Percoll centrifugation and PECAM-1 antibodies eliminated the undifferentiated cells expressing Oct-3/4 from the EB-derived cells. ES-cell-derived hepatocytes showed expression of liver-related genes, synthesis of urea and glycogen, and structural characteristics during subculture. A transplantation study showed that the enriched ES-cell-derived hepatocytes integrated into the injured mouse liver and produced no teratomas. When the ES-cell-derived hepatocytes were transplanted into a CCl4-injured liver, the liver function was subsequently improved. CONCLUSIONS: Functional hepatocytes can be differentiated from mouse ES cells by way of EB formation. The elimination of undifferentiated cells from the EBs provides transplantable cells for liver failure without tumorigenicity.     

Insertion of a suicide gene into an immortalized human hepatocyte cell line

For developing a bioartificial liver (BAL) device, an attractive alternative to the primary human hepatocytes would be the use of highly differentiated immortalized human hepatocytes with a safeguard. To test the feasibility, the primary human hepatocytes were immortalized by a plasmid SV3neo encoding simian virus 40 large T antigen (SV40Tag) gene. A highly differentiated hepatocyte line OUMS-29 was established. A suicide gene of herpes simplex virus-thymidine kinase (HSV-TK) was retrovirally introduced into OUMS-29 cells as a safeguard for clinical application. One of the resulting HSV-TK-positive cell lines, OUMS-29/tk, grew in chemically defined serum-free medium with the gene expression of differentiated liver functions. OUMS-29/tk cells were 100 times more sensitive to ganciclovir compared with unmodified OUMS-29 cells in in vitro experiments. We have established a tightly regulated immortalized human hepatocyte cell line. Essentially unlimited availability of OUMS-29/tk cells may be clinically useful for BAL therapy.