Ocular immune privilege is circumvented by CD4+ T cells, leading to the rejection of intraocular tumors in an IFN-{gamma}-dependent manner

Although intraocular tumors reside in an immune-privileged site, they can circumvent immune privilege and undergo rejection, which typically follows one of two pathways. One pathway involves CD4(+) T cells, delayed-type hypersensitivity (DTH), and the culmination in ischemic necrosis of the tumor and phthisis (atrophy) of the eye. The second pathway is DTH-independent and does not inflict collateral injury to ocular tissues, and the eye is preserved. In this study, we used a well-characterized tumor, Ad5E1, to analyze the role of IFN-gamma in the nonphthisical form of intraocular tumor rejection. The results showed that IFN-gamma induced tumor cell apoptosis, inhibited tumor cell proliferation, and promoted rejection by inhibiting angiogenesis. Microarray analysis revealed that IFN-gamma induced up-regulation of five antiangiogenic genes and down-regulation of four proangiogenic genes in Ad5E1 tumor cells. Although IFN-gamma knockout (KO) mice have progressively growing intraocular tumors, IFN-gamma was not needed for the elimination of extraocular tumors, as all IFN-gamma KO mice rejected s.c. tumor inocula. This represents a heretofore unrecognized role for IFN-gamma in circumventing ocular immune privilege and eliminating intraocular tumors. The findings also reveal that some IFN-gamma-independent tumor rejection processes are excluded from the eye and may represent a new facet of ocular immune privilege.     

Anti-class II antibodies, but not cytotoxic T-lymphocyte antigen 4-immunoglobulin hybrid molecules, prevent rejection of major histocompatibility complex class II-negative myeloma in T-cell receptor-transgenic mice

We have previously shown that tumour-specific CD4+ T cells protect against subcutaneous injections of major histocompatibility complex (MHC) class II-negative MOPC315 myeloma cells. Here, we have interfered with the immunologic events that lead to successful rejection of MOPC315 challenges in T-cell receptor (TCR)-transgenic mice. The CD4+ T cells have a transgene-encoded TCR specific for a MOPC315 V-region idiotypic (Id) peptide presented on the MHC class II molecule E(d). A side-by-side comparison indicated that DNA-recombination-deficient TCR-transgenic mice were better protected against MOPC315 tumour development than recombination-sufficient counterparts, suggesting that B cells or endogenous TCR chains might facilitate tumour progression in this model. Intraperitoneal injections of E(d)-specific antibodies over a period of initial 24 days, abrogated protection against tumours in both strains of mice. By contrast, injections of anticostimulatory molecules (cytotoxic T-lymphocyte antigen 4-immunoglobulin hybrid molecules) had no effect. The findings demonstrate that tumour rejection depends on the presence of MHC class II molecules, despite the fact that MOPC315 tumour cells themselves do not express them. The results are consistent with the idea that secreted myeloma protein is processed and presented by class II+ antigen-presenting cells to Id-specific na?ve CD4+ T cells that become activated and kill the myeloma cells by a bystander mechanism. While Id presentation on class II molecules is absolutely required for tumour rejection, costimulatory CD80/CD86 molecules might be dispensible in this process.     

CD8+ T cells are crucial for the ability of congenic normal mice to reject highly immunogenic sarcomas induced in nude mice with 3-methylcholanthrene

An attempt was made to identify the selection pressures put upon a growing tumour by CD8+ T cells. To this end tumours induced with 3-methylcholanthrene in T cell-deficient nude mice and in congenic T cell-competent nu/+ mice were transplanted to nu/+ recipients. The rejection rate of the sarcomas from nude mice was almost twice that of the sarcomas from nu/+ mice. Depletion of CD8+ T cells from nu/+ recipients prior to transplantation made them accept nude tumours that were consistently rejected by untreated nu/+ recipients. These findings suggest that a methylcholanthrene sarcoma during its growth in a T cell-competent host adapts to the T cell system through a selective elimination of highly immunogenic tumour cells that are susceptible to CD8+ T cell-mediated lysis.     

Regulatory T cells inhibit Fas ligand-induced innate and adaptive tumour immunity

CD4+CD25+ regulatory T cells (Treg) are known to influence T cell responses to tumours. Here we have explored the role of Treg in inhibiting not only adaptive, but also innate immune responses to tumours. To this end we used a Fas ligand (FasL)-expressing melanoma cell line in a mouse model. In this system, innate immunity is sufficient to reject the tumour. All mice depleted of Treg and challenged with FasL-expressing melanoma remained tumour-free. Investigation of the underlying cellular effector mechanisms revealed that depletion of Treg enhanced an NK cell response capable of tumour lysis. Furthermore, this initial innate immune response primed mice to make an effective adaptive immune response leading to complete rejection of challenge with the parental melanoma. Both antigen-specific antibody and CD4+ T cells were implicated in protection via adaptive immunity. We conclude that removal of Treg and vaccination with whole tumour cells expressing FasL activates multiple arms of the immune system, leading to efficient tumour rejection. These findings highlight a novel role for FasL in inducing innate immune responses that are normally inhibited by Treg and uncover an adjuvant effect of FasL that can be used to stimulate tumour immunity after depletion of Treg.     

Capacity of CD8+ T Cells to Reject Immunogenic Variants of a Spontaneous Murine Carcinoma: Lack of Non-Specific (NK1.1+) Effector Mechanisms

Class I MHC-expressing (Ia-) immunogenic (imm +) variants, which elicit a strong syngeneic host immune rejection response, can be isolated following 5-azacytidine treatment from the MHC-negative non-immunogenic (imm-) murine carcinoma cell line SP1 (10.1 subclone). In the present study, we have shown that CD4-depleted CD8+ T cells are both necessary and sufficient for the rejection process. Treatment of semi-syngeneic B6 X CBA F1 mice with anti-NK1.1 antibodies had no effect on the rejection of immunogenic variants, although the splenic NK (natural killer) activity of recipients was fully abrogated. Thus NK1.1+ effectors, which include most NK and LAK (lymphokine activated killer) cells, are most likely not involved in the rejection process. This finding was supported by a complete lack of NK susceptibility of SP1 cells in vitro, although variable killing by LAK and poly-I: C-induced killer cells was observed. To assess the role of NK1.1-LAK and other non-T killers (e.g. cytolytic macrophages) in vivo, we determined the specificity of the rejection process. We examined the ability of immune animals to reject a mixture of non-immunogenic parent tumour cells (or cells of an unrelated syngeneic tumour) and of the variant tumour cells used for the initial immunization. Growth of the parent tumour cells was unaffected while the same animals rejected the immunogenic tumour cells. Our findings support a primary role of tumour-specific CD8+ T cells in the rejection of imm+ variants with no detectable involvement of non-specific effector cells in the tumour destruction process.     

Loss of natural killer T cells promotes pancreatic cancer in LSL‐KrasG12D/+ mice

The role of the unique T‐cell population, natural killer T (NKT) cells, which have similar functions to NK cells in pancreatic cancer (PC), is not yet evaluated. To address the regulatory roles of NKT cells on tumour progression through tumour‐associated macrophages (TAM) and their production of microsomal prostaglandin E synthase‐1 (mPGES‐1) and 5‐lipoxygenase (5‐LOX) in (Kras)‐driven pancreatic tumour (KPT) progression, we crossed CD1d^−/− mice deficient in both invariant and variant NKT cells with the Kras^G12D mice. Loss of NKT cells significantly increased pancreatic intraepithelial neoplasia (PanIN) lesions and also increased 5‐LOX and mPGES‐1 expression in M2‐type macrophages and cancer stem‐like cells in pancreatic tumours. Pharmacological inhibition of mPGES‐1 and 5‐LOX in M2 macrophages with specific inhibitor YS‐121 in KPT‐CD1d^−/− mice decreased PanIN lesions and suppressed tumour growth in association with elevated levels of active CD8a cells. Hence, NKT cells regulate PC by modulating TAMs (M2) through mPGES‐1 and 5‐LOX; and the absence of NKT cells leads to aggressive development of PC.     

Immune privilege, T-cell tolerance, and tissue-restricted autoimmunity

The eye is one of several specialized organs/tissues that display immune privilege, i.e. sites that permit foreign tissue grafts to enjoy prolonged (or even indefinite) survival. Immune privilege is an active, rather than a passive, process in which specialized tissues/sites and the immune system collaborate in providing immune protection without the risk of immunopathogenic injury to the tissue itself. Among the mechanisms that have been found to contribute to immune privilege is tolerance of peripheral T cells. Over the past few years, investigators have demonstrated at least four different pathways by which immune privilege can lead to T-cell tolerance: clonal deletion, clonal anergy, immune deviation, and T-cell suppression. In the case of the eye, privilege exists in part because antigens introduced into the eye are captured by distinctive local antigen-presenting cells that migrate via the blood to the spleen. At that site, they generate a stereotypic systemic immune response that is deficient in CD4⁺ T cells that mediate delayed hypersensitivity and that help B cells to secrete complement-fixing antibodies, yet replete with CD8⁺ T cells that function as cytotoxic cells and as regulatory cells. This response, termed anterior chamber associated immune deviation (ACAID), is mediated by antigen-specific regulatory T cells that secrete TGFβ in an autocrine fashion and suppress effector functions of inflammogenic CD4⁺ T cells. Because intraocular inflammation is deleterious to vision, ACAID and immune privilege are considered to be evolutionary adaptations that enable the eye to benefit from immune protection against pathogens without suffering blindness from immune injury.     

Antitumour activity mediated by CD4+ cytotoxic T lymphocytes against MHC class II-negative mouse hepatocellular carcinoma induced by dendritic cell vaccine and interleukin-12

When BALA/c mice with BNL hepatocellular carcinoma (HCC) were treated with dendritic cells fused with BNL cells (DC/BNL) and recombinant murine interleukin (IL)-12, tumour development was significantly suppressed, whereas treatment with either DC/BNL or IL-12 alone did not show a tumour-suppressive effect. Antitumour activity induced by DC/BNL + IL-12 was abrogated by depletion of CD4+ T cells, but not by depletion of CD8+ T cells or natural killer cells. Splenic CD4+ T cells and CD8+ T cells from DC/BNL-treated mice showed cytotoxic activity against BNL cells after 3 days of incubation with DC/BNL, although BNL cells do not express major histocompatibility complex (MHC) class II molecules even after treatment with interferon (INF)-gamma. Furthermore, CD4+ T cells killed syngeneic-irrelevant CT26 cells and even allogeneic Hepa1-6 cells. This cytotoxicity was blocked by concanamycin A, but not by an anti-Fas ligand (FasL) monoclonal antibody, indicating that cytotoxic activity was mediated by perforin. Immunofluorescence microscopy demonstrated that abundant CD4+ T cells and MHC class II-positive macrophages, but not CD8(+) T cells, had infiltrated tumour tissue in mice treated with DC/BNL + IL-12. Flow cytometric analysis of tumour-infiltrating cells in mice treated with DC/BNL + IL-12 showed increases in CD4+ T cells and MHC class II+ CD11b+ cells but not in CD8+ T cells or MHC class I+ CD11b+ cells. Our results suggest that, in BNL-bearing mice treated with DC/BNL + IL-12, tumour macrophages activated by INF-gamma produced by IL-12-stimulated T cells might present BNL tumour antigens and activate DC/BNL-primed CD4+ cytotoxic T lymphocytes (CTLs) in a MHC class II-dependent manner, leading to perforin-mediated bystander killing of neighbouring MHC class II-negative tumour cells.     

Ocular immune privilege: the eye takes a dim but practical view of immunity and inflammation

The delicate visual axis that makes precise vision possible is highly vulnerable to the destructive potential of immunogenic inflammation. Immune privilege of the eye is the experimental expression of the way in which evolution has coped with the countermanding threats to vision of ocular infections and ocular immunity and inflammation. Ocular immune privilege has five primary features that account for its existence: blood:ocular barriers, absent lymphatic drainage pathways, soluble immunomodulatory factors in aqueous humor, immunomodulatory ligands on the surface of ocular parenchymal cells, and indigenous, tolerance-promoting antigen-presenting cells (APCs). Three manifestations of ocular immune privilege that have received the most extensive study are the intraocular microenvironment, which is selectively anti-inflammatory and immunosuppressive; the prolonged acceptance of solid tissue and tumor allografts in the anterior chamber; and the induction of systemic tolerance to eye-derived antigens. Anterior chamber-associated immune deviation is known to arise when indigenous, ocular APCs capture eye-derived antigens and deliver them to the spleen where multicellular clusters of these cells, natural killer T cells, marginal zone B cells, and gammadelta T cells create an antigen-presentation environment that leads to CD4(+) and CD8(+) alpha/beta T cells, which as regulators, suppress induction and expression of T helper cell type 1 (Th1) and Th2 immune expression systems. The ways the eye influences local and systemic immune responses to ocular antigens and pathogens carry risks to and benefits for mammalian organisms. As loss of sight is a powerful, negative-selecting force, the benefits of ocular immune privilege outweigh the risks.     

Differential Expression of Major Histocompatibility Complex Class II Variants in Cells Infiltrating the Meth A Sarcoma

CD4+ T cells are involved in immune responses against the Meth A sarcoma and infiltrate tumours arising from Meth A cells inoculated intradermally in (BALB/c x C57BL/6)F1 (H-2d/b) mice. In order to investigate whether the prerequisites for tumour antigen presentation to CD4+ T cells are fulfilled within the malignant lesion, expression of class II major histocompatibility complex (MHC) molecules and the costimulatory ligand B7 were examined. The I-Ab and I-Ed allomorphs were abundantly expressed by virtually all B cells and 50% of macrophages infiltrating the tumours. In striking contrast, the I-Ad variant was hardly detectable. This pattern of class II expression appeared to be unique for the tumour microenvironment. Thus the proportion of I-Ad+ spleen B cells and peritoneal macrophages did not significantly differ from the proportion expressing I-Ab and I-Ed, and these extratumoral I-Ad+ cells stained as brightly as did cells from healthy mice. Expression of B7 was weak by tumour-infiltrating cells. The profound capacity of the Meth A sarcoma to confer low local I-Ad and B7 expression might preclude T-cell-dependent anti-tumour immune responses and thus promote survival of malignant cells. Whereas MHC class II genes are generally found to be co-ordinately transcribed, this study demonstrates that the expression of MHC class II allelic variants can be differentially regulated in vivo.     

Blockade of endogenous B7-H1 suppresses antibacterial protection after primary Listeria monocytogenes infection

B7-H1 (also known as CD274 and PD-L1) is a cosignalling molecule regulating T-cell immunity positively or negatively in vivo. However, little is known about the role of endogenous B7-H1 in bacterial infection. We found that B7-H1 expression was up-regulated in various cell populations including CD4+ and CD8+ T cells, natural killer (NK) cells and macrophages following Listeria monocytogenes infection. Administration of the antagonistic B7-H1 monoclonal antibody resulted in a significant increase in mortality in mice infected with a lethal dose of L. monocytogenes compared with mice given the control immunoglobulin. In vivo blockade of B7-H1 greatly inhibited the production of tumour necrosis factor (TNF)-alpha and nitric oxide, key effector molecules responsible for intracellular killing by macrophages. B7-H1 blockade also suppressed the expression of granzyme B and interferon (IFN)-gamma by NK cells. Interestingly, blocking of endogenous B7-H1 selectively inhibited CD8+ T cells rather than CD4+ T cells in response to L. monocytogenes infection, as evidenced by the reduction of IFN-gamma production and the expression of effector surface markers including CD62L(int/low) and CD44(high) in CD8+ T cells from mice given anti-B7-H1 monoclonal antibody. In addition, we found that the proliferation of listeriolysin-O (LLO)-specific and IFN-gamma-producing L. monocytogenes-reactive CD8+ T cells was significantly decreased not only in the effector phase but also in the memory phase in the presence of anti-B7-H1 antibody. Our findings thus suggest that endogenous B7-H1 can provide positive costimulatory signals for innate and adaptive immunity leading to protection against intracellular bacterial infection.     

Antigen-independent cross-talk between macrophages and CD8+ T cells facilitates their cooperation during target destruction

Inflammatory sites associated with tissue destruction often contain a complex mixture of cells including macrophages as well as CD8+ and CD4+ T cells. Here, we have investigated, using islets of Langerhans as targets, if CD8+ T cells and macrophages can cooperate in tissue destruction. CD8+ T cells obtained from the islet inflammatory lesion of non-obese diabetic mice or cloned islet-specific CD8+ T cells were ineffective in destroying islets on their own. Including increasing numbers of macrophages in co-cultures of islets and islet-derived or cloned CD8+ T cells progressively increased and accelerated islet destruction. Macrophages alone were ineffective. Macrophage-depleted islets were not destroyed by islet-derived CD8+ T cells. For cooperative islet destruction to occur, beta cells, but not macrophages, needed to be able to present antigens to CD8+ T cells. CD8+ T cells triggered NO production by macrophages, while macrophages triggered IFN-gamma production by CD8+ T cells. Each of these factors was partially effective, but not sufficient, for maximal islet destruction. Antibodies specific for ICAM-1 and LFA-1 inhibited both cooperative islet destruction and cross-stimulation of CD8+ T cells and macrophages. The data suggest that if CD8+ T cells become only weakly activated by target cells, they are not able to destroy target tissue on their own. However, such CD8+ T cells and local macrophages may still cross-stimulate each other, which then facilitates target destruction. For this to occur, target cells, but not macrophages, need to present antigen to CD8+ T cells.     

Water extract of pilose antler can inhibit breast cancer progression of the mouse through modulating its immune system

Pilose antler (PA) is used to treat many diseases, but its effect on breast cancer is still unclear. Here, we report the effects of PA on the growth of the mouse mammary tumour in vitro and in vivo, and its effects on immune system of the tumor-bearing mice. The 4T1 mouse mammary tumour cells were cultured with media supplemented with water extract of PA (WEPA), and the female BALB/c mice transplanted with 4T1 cells were treated by gavage with WEPA. The results showed that WEPA promoted the proliferation of 4T1 cells in vitro, while inhibited the growth of 4T1 tumour in vivo. In addition, WEPA increased the proportion of CD4+ T cells, CD8+ T cells and NK cells and reduced myeloid-derived suppressive cells in mouse peripheral blood. These results suggest that WEPA can inhibit the growth of mouse 4T1 tumours through modulating immune system of the mouse.     

Density and phenotype of tumour-associated mononuclear cells in colonic carcinomas determined by computer-assisted video image analysis.

The density and phenotypes of tumour-associated mononuclear cells (TAMC) in tissue sections of colonic carcinomas was determined by the technique of video image analysis (VIA). This technique allowed an accurate and objective enumeration of both total mononuclear cells (MC) in H&E stained sections and individual types of cells as revealed by immunoperoxidase staining with monoclonal antibodies in frozen sections. This enumeration allowed reliable statistical analysis of the differences between sample groups. Using this technique it was found that the density of MC in histiologically normal tissue was significantly higher than in tumour tissue. Tumours from patients with the best prognosis (stage A) had significantly higher numbers of TAMC than stage B (P less than 0.02), C (P less than 0.002) and D (P less than 0.002) tumours. The differences in the density of TAMC between tumours obtained from stage B and C and that between C and D were not significant, whereas stage B had a significantly higher TAMC density than stage D tumours (P less than 0.05). Comparing tumour differentiation, well differentiated adenocarcinomas had a significantly higher (P less than 0.05) TAMC density than poorly differentiated tumours but not moderately differentiated tumours. Moderately and poorly differentiated adenocarcinomas did not differ significantly in the density of TAMC. In examining the phenotype of these cells, it was found that T lymphocytes formed the majority of the TAMC with the CD4+ subset predominating in 28 of 29 cases. Similarly, all sections of normal colon (taken at least 4 cm away from the tumour) had more CD4+ than CD8+ cells. The proportion of the total leucocyte population that was CD3+ was comparable in normal and tumour tissue. Generally, few macrophages were present in either tumour or normal tissues. B cells (CD21%) and subset of NK cells (CD57+) were not detected in the tumours. There were no significant differences in the proportion of leucocytes which were CD4+, CD8+ and CD14+ (macrophages) between the normal colon and the tumour tissues. The types of cells in the TAMC population did not differ with tumour stage or differentiation or with the density of the TAMC itself.     

Anti-idiotype antibody induced cellular immunity in mice transgenic for human carcinoembryonic antigen

In the present study, we have analysed the detailed cellular immune mechanisms involved in tumour rejection in carcinoembryonic antigen (CEA) transgenic mice after immunization with dendritic cells (DC) pulsed with an anti-idiotype (Id) antibody, 3H1, which mimics CEA. 3H1-pulsed DC vaccinations resulted in induction of CEA specific cytotoxic T lymphocyte (CTL) responses in vitro and the rejection of CEA-transfected MC-38 murine colon carcinoma cells, C15, in vivo (Saha et al.,Cancer Res 2004; 64: 4995-5003). These CTL mediated major histocompatibility complex (MHC) class I-restricted tumour cell lysis, production of interferon-gamma (IFN-gamma) and tumour necrosis factor-alpha (TNF-alpha), and expression of Fas ligand (FasL) and TNF-related apoptosis-inducing ligand (TRAIL) in response to C15 cells. CTL used perforin-, FasL-, and TRAIL-mediated death pathways to lyse C15 cells, although perforin-mediated killing was the predominant lytic mechanism in vitro. The cytokines IFN-gamma and TNF-alpha synergistically enhanced surface expression of Fas, TRAIL receptor, MHC class I and class II on C15 cells that increased the sensitivity of tumour cells to CTL lysis. CTL activity generated in 3H1-pulsed DC immunized mice was directed against an epitope defined by the idio-peptide LCD-2, derived from 3H1. In vivo lymphocyte depletion experiments demonstrated that induction of CTL response and antitumour immunity was dependent on both CD4+ and CD8+ T cells. The analysis of splenocytes of immunized mice that had rejected C15 tumour growth revealed up-regulated surface expression of memory phenotype Ly-6C and CD44 on both CD4+ and CD8+ T cells. The adoptive transfer experiments also suggested the role of both CD4+ and CD8+ T cells in this model system. Furthermore, mice that had rejected C15 tumour growth, developed tumour-specific immunological memory.     

CD5 blockade enhances ex vivo CD8+ T cell activation and tumour cell cytotoxicity

CD5 is expressed on T cells and a subset of B cells (B1a). It can attenuate TCR signalling and impair CTL activation and is a therapeutic targetable tumour antigen expressed on leukemic T and B cells. However, the potential therapeutic effect of functionally blocking CD5 to increase T cell anti-tumour activity against tumours (including solid tumours) has not been explored. CD5 knockout mice show increased anti-tumour immunity: reducing CD5 on CTLs may be therapeutically beneficial to enhance the anti-tumour response. Here, we show that ex vivo administration of a function-blocking anti-CD5 MAb to primary mouse CTLs of both tumour-naïve mice and mice bearing murine 4T1 breast tumour homografts enhanced their capacity to respond to activation by treatment with anti-CD3/anti-CD28 MAbs or 4T1 tumour cell lysates. Furthermore, it enhanced TCR signalling (ERK activation) and increased markers of T cell activation, including proliferation, CD69 levels, IFN-γ production, apoptosis and Fas receptor and Fas ligand levels. Finally, CD5 function-blocking MAb treatment enhanced the capacity of CD8⁺ T cells to kill 4T1-mouse tumour cells in an ex vivo assay. These data support the potential of blockade of CD5 function to enhance T cell-mediated anti-tumour immunity.     

RGD capsid modification enhances mucosal protective immunity of a non‐human primate adenovirus vector expressing Pseudomonas aeruginosa OprF

Replication‐deficient adenoviral (Ad) vectors of non‐human serotypes can serve as Ad vaccine platforms to circumvent pre‐existing anti‐human Ad immunity. We found previously that, in addition to that feature, a non‐human primate‐based AdC7 vector expressing outer membrane protein F of P. aeruginosa (AdC7OprF) was more potent in inducing lung mucosal and protective immunity compared to a human Ad5‐based vector. In this study we analysed if genetic modification of the AdC7 fibre to display an integrin‐binding arginine–glycine–aspartic acid (RGD) sequence can further enhance lung mucosal immunogenicity of AdC7OprF. Intratracheal immunization of mice with either AdC7OprF.RGD or AdC7OprF induced robust serum levels of anti‐OprF immunoglobulin (Ig)G up to 12 weeks that were higher compared to immunization with the human vectors Ad5OprF or Ad5OprF.RGD. OprF‐specific cellular responses in lung T cells isolated from mice immunized with AdC7OprF.RGD and AdC7OprF were similar for T helper type 1 (Th1) [interferon (IFN)‐γ in CD8⁺ and interleukin (IL)‐12 in CD4⁺], Th2 (IL‐4, IL‐5 and IL‐13 in CD4⁺) and Th17 (IL‐17 in CD4⁺). Interestingly, AdC7OprF.RGD induced more robust protective immunity against pulmonary infection with P. aeruginosa compared to AdC7OprF or the control Ad5 vectors. The enhanced protective immunity induced by AdC7OprF.RGD was maintained in the absence of alveolar macrophages (AM) or CD1d natural killer T cells. Together, the data suggest that addition of RGD to the fibre of an AdC7‐based vaccine is useful to enhance its mucosal protective immunogenicity.     

Does innate immune privilege exist?

Immune privilege in the eye is believed to originate from the eye's need to avoid the sight-destroying consequences of inflammation. Over the past 25 years, many of the anatomical, cellular, and molecular mechanisms by which the eye avoids inflammation secondary to adaptive immune responses have been elucidated. In the recent past, it has become increasingly clear that innate immune responses play a critical role in activating the adaptive immune response. Moreover, innate immunity itself carries a heavy burden of inflammation, thereby posing a threat to vision if it should occur intraocularly. Ocular immunologists have now begun to inquire into the extent to which the eye regulates the expression of innate immunity in oculi. Evidence is presented which indicates that factors found in normal aqueous humor (1) prevent NK cells from lysing their targets, (2) inhibit neutrophil activation by CD95 ligand, (3) suppress nitric oxide production by activated macrophages, and (4) interfere with complement activation via the alternative pathway. These factors include transforming growth factor-beta2, alpha-melanocyte-stimulating hormone, calcitonin gene-related peptide, and migration inhibitory factor. The ability of the eye to prevent intraocular activation of innate immune effectors spares the corneal endothelium (which expresses CD95 ligand constitutively, but low levels of MHC class I molecules) from destruction by NK cells and neutrophils, and protects the visual axis from distortion by macrophage and complement-mediated inflammation. Thus, privilege exists in the eye for both adaptive and innate immunity.     

Immunological mechanisms elicited at the tumour site by lymphocyte activation gene-3 (LAG-3) versus IL-12: sharing a common Th1 anti-tumour immune pathway

The experimentally induced TS/A murine mammary carcinoma is poorly immunogenic and mainly infiltrated by antigen-presenting cells (APCs), namely macrophages and immature dendritic cells (DCs). Human (h) and mouse (m) lymphocyte activation gene-3 (LAG-3 or CD233) is a physiological MHC class II ligand and powerful APC activator. A gene transfer approach has revealed its anti-tumour activity in this model: hLAG-3 was more effective than mLAG-3. To obtain a clearer picture of the immunoregulatory mechanisms associated with the rejection dynamics of h- and m-LAG-3 transfectants, immunohistochemistry and confocal microscopy analyses of TS/A-hLAG-3, TS/A-mLAG-3, and control TS/A-pc tumours were performed. The immune events elicited by mLAG-3 and m-interleukin (IL)-12 were also compared, since their rejection kinetics were quite similar, and LAG-3 enables IL-12 production by macrophages and DCs. Both the TS/A-h- and, to a lesser extent, the m-LAG-3 rejection areas were characterized by an impressive recruitment of APCs, granulocytes, NK cells, CD4+ T lymphocytes and CD8+ IFNgamma-expressing cells. In both cases, infiltration by APCs was accompanied by strong CD80 and CD86 expression and macrophage nitric oxide (NO) synthase up-regulation. Distinct expression of IL-12 and CXCL9 was also found, especially in the draining lymph nodes. T lymphocytes and CD86-expressing APCs were significantly prevalent in both the TS/A-h- and the m-LAG-3 compared with the TS/A-mIL-12 rejection area. Production of IFNgamma, TNFalpha and IL1beta, and chemokines, namely CXCL5, CXCL9, CXCL10, CXCL11, CCL5, and CCL2, by infiltrating leukocytes and signs of defective neovascularization were detected in tumours expressing h-LAG-3-, m-LAG-3-, and m-IL-12. However, IFNgamma, CCL2, and CCL5 production prevailed in the TS/A-hLAG-3 rejection area. Taken together, these results indicate that LAG-3 expression by engineered tumour cells efficiently promotes intra-tumoural recruitment, activation, and Th1 commitment of APCs, and leads to a wide intra-tumoural influx of non-specific and specific reactive cells, and the release of immunoregulatory and cytotoxic mediators. Many of LAG-3's anti-tumour activities are shared with IL-12.     

HLA-DR antigen expression and lymphocyte subsets in transitional cell carcinoma of the urinary bladder. An immunohistological study on frozen sections

Lymphocyte subpopulations (B cells, CD4, CD8), interleukin-20 receptors (IL-2), monocytes/macrophages (Leu M₅), and HLA-DR antigen expression were studied immunohistochemically on frozen sections from 38 bladder cancer specimens. T cells predominated over B cells in all tumours. CD4-positive lymphocytes predominated over CD8 in the stroma (CD4/CD8: 1·35/1), while in epithelial tumour cells CD8 was the prominent subpopulation (CD8/CD4: 1·75/1). Aberrant HLA-DR expression was found in 21·05 per cent of bladder tumours. A strong correlation between CD4 and CD8 population densities and macrophages with the other subpopulations was noticed. In HLA-DR-positive tumours, there was no correlation of the percentage of positive cells with CD4- and CD8-positive lymphocyte populations. Various parameters including IL-2 receptors, B cells, CD8- and CD4-positive cells, and macrophages did not differ significantly between the groups of tumours expressing and not expressing HLA-DR antigen. There were no statistically significant differences in the population densities of B cells, CD8- or CD4-positive cells, IL-2 receptor, monocytes/macrophages, and HLA-DR antigen expression among various clinicopathological parameters, including growth pattern, histological grade and clinical stage or patient's age and sex. These findings suggest that in transitional cell carcinoma of the urinary bladder, HLA-DR antigen expression is independent of lymphocyte subpopulations. It is therefore possible that HLA-DR expression by tumour cells reflect the existence of separate HLA-DR-positive or HLA-DR-negative tumour clones.