Poly(gamma-glutamic acid) nanoparticles as an efficient antigen delivery and adjuvant system: potential for an AIDS vaccine

Antigen delivery systems using polymeric nanoparticles are of special interest as stable protein-based antigen carriers. In the present study, novel biodegradable poly(gamma-glutamic acid) (gamma-PGA) nanoparticles were examined for their antigen delivery and immunostimulatory activities in vitro and in vivo. The uptake of ovalbumin by dendritic cells was markedly enhanced by gamma-PGA nanoparticles, and the ovalbumin was gradually released from gamma-PGA nanoparticles into the cells. In addition, gamma-PGA nanoparticles appeared to have great potential as an adjuvant, because they could induce the maturation of dendritic cells. Although not only ovalbumin-encapsulating nanoparticles (OVA-NPs) but also a simple mixture of ovalbumin and nanoparticles induced dendritic cell maturation, the only dendritic cells exposed to OVA-NPs could strongly activate antigen-specific interferon (IFN)-gamma-producing T cells. Subcutaneous immunization of mice with human immunodeficiency virus type 1 (HIV-1) p24-encapsulating nanoparticles activated antigen-specific IFN-gamma-producing T cells in spleen cells and induced p24-specific serum antibodies, as compared to immunization with p24 alone. Like ovalbumin, a mixture of p24 and nanoparticles also induced antigen-specific serum antibodies but did not activate IFN-gamma-producing T cells in spleen cells, suggesting that nanoparticles play a critical role in inducing cellular immune responses. Furthermore, gamma-PGA nanoparticles had a capacity comparable to that of the complete Freund's adjuvant (CFA) in inducing p24-specific serum antibody. However, unlike CFA, they predominantly activated p24-specific IFN-gamma-producing T cells. Thus, gamma-PGA nanoparticles encapsulating various antigens may have great potential as novel and efficient protein-based vaccines against infectious diseases, including HIV-1 infection.     

PSA-based vaccines for the treatment of prostate cancer

Prostate cancer is the second leading cause of cancer-related death among men in the USA. Vaccine strategies represent a novel therapeutic approach. One potential target for a prostate cancer vaccine is prostate-specific antigen, owing to its restricted expression in prostate cancer and normal prostatic epithelial cells. A number of prostate-specific antigen-specific epitopes have been identified that can activate cytotoxic T lymphocytes and, in turn, result in the killing of tumor targets by the peptide-specific cytotoxic T lymphocytes. Strategies employed in clinical trials consist of dendritic cell vaccines, recombinant protein and recombinant DNA vaccines, as well as viral vector delivery of vaccines. New approaches incorporating a combination of a vaccine with traditional treatments for prostate cancer are also being investigated.     

Effects of the tumor microenvironment on the efficacy of tumor immunotherapy

Cancer immunotherapy utilizes vaccines targeting tumor antigens or tumor endothelium to prevent or regress tumors. Many cancer vaccines are designed to induce antigen-specific effector T cells that migrate to the tumor site. In an optimal situation, the effector T cells penetrate the tumor, release their effector molecules, induce tumor cell death and tumor regression. However, the tumor microenvironment is frequently immunosuppressive and contributes to a state of immune ignorance, impacting on the vaccine's ability to break tolerance to tumor antigen/s. This review discusses the factors in the tumor microenvironment that can affect the efficacy of cancer vaccines. In particular, the review focuses on pathways leading to effector T cell penetration of tumors or the inhibition of this process.     

Effects of the Tumor Microenvironment on the Efficacy of Tumor Immunotherapy

Cancer immunotherapy utilizes vaccines targeting tumor antigens or tumor endothelium to prevent or regress tumors. Many cancer vaccines are designed to induce antigen-specific effector T cells that migrate to the tumor site. In an optimal situation, the effector T cells penetrate the tumor, release their effector molecules, induce tumor cell death and tumor regression. However, the tumor microenvironment is frequently immunosuppressive and contributes to a state of immune ignorance, impacting on the vaccine's ability to break tolerance to tumor antigen/s. This review discusses the factors in the tumor microenvironment that can affect the efficacy of cancer vaccines. In particular, the review focuses on pathways leading to effector T cell penetration of tumors or the inhibition of this process.     

Effects of the Tumor Microenvironment on the Efficacy of Tumor Immunotherapy

Cancer immunotherapy utilizes vaccines targeting tumor antigens or tumor endothelium to prevent or regress tumors. Many cancer vaccines are designed to induce antigen-specific effector T cells that migrate to the tumor site. In an optimal situation, the effector T cells penetrate the tumor, release their effector molecules, induce tumor cell death and tumor regression. However, the tumor microenvironment is frequently immunosuppressive and contributes to a state of immune ignorance, impacting on the vaccine's ability to break tolerance to tumor antigen/s. This review discusses the factors in the tumor microenvironment that can affect the efficacy of cancer vaccines. In particular, the review focuses on pathways leading to effector T cell penetration of tumors or the inhibition of this process.     

树突状细胞肿瘤疫苗的研究进展

树突状细胞(DC)是目前发现的功能最强大的专职抗原递呈细胞(APC),能激活静息T细胞并使其增殖,产生抗原特异性细胞毒性T淋巴细胞(CTL),从而发挥抗肿瘤免疫效应.近年来,人们在肿瘤疫苗的研究中,采用多种策略制备DC肿瘤疫苗,尝试通过改变机体免疫系统对肿瘤的免疫状态来加强机体的免疫功能,进而清除肿瘤细胞,而对正常组织几乎无伤害,因此有很好的临床应用前景.     

Dendritic cell as therapeutic vaccines against tumors and its role in therapy for hepatocellular carcinoma

Dendritic cells （DCs） are the most potent professional antigen-presenting cells, and capable of stimulating naive T cells and driving primary immune responses. DCs are poised to capture antigen, migrate to draining lymphoid organs, and after a process of maturation, select antigen-specific lymphocytes to which they present the processed antigen, thereby inducing immune responses. The development of protocols for the ex vivo generation of DCs may provide a rationale for designing and developing DC-based vaccination for the treatment of tumors. There are now several strategies being applied to upload antigens to DCs and manipulate DC vaccines. DC vaccines are able to induce therapeutic and protective antitumor immunity. Numerous studies indicated that hepatocellular carcinoma （HCC） immunotherapies utilizing DC-presenting tumor-associated antigens could stimulate an antitumour T cell response leading to clinical benefit without any significant toxicity. DC-based tumor vaccines have become a novel immunoadjuvant therapy for HCC. Cellular ＆ Molecular Immunology. 2006;3（3）：197-203.     

Ex vivo expansion of human cytomegalovirus-specific cytotoxic T cells by recombinant polyepitope: implications for HCMV immunotherapy

Stem cell transplantation (SCT) remains the most effective curative therapy for the majority of hematopoietic malignancies. Unfortunately, SCT is limited by its toxicity and infectious complications that result from profound immunosuppression. In particular, acquisition of exogenous or reactivation of endogenous human cytomegalovirus (HCMV) is common after SCT. More recently, reconstitution of host immunity through augmentation of anti-HCMV T cell responses has been proposed as an exciting candidate therapy to avoid the requirement for antiviral drug use. Here we have developed a novel antigen presentation system based on a replication-deficient adenovirus that encodes multiple HLA class I-restricted epitopes from eight different antigens of HCMV as a polyepitope (referred to as AdCMVpoly). Ex vivo stimulation of peripheral blood mononuclear cells with AdCMVpoly consistently showed rapid stimulation and expansion of multiple epitope-specific T cells that recognized endogenously processed epitopes presented on virus-infected cells. Interestingly, the AdCMVpoly expression system is capable of expanding antigen-specific T cells even in the absence of CD4(+) T cells. These studies show the effectiveness of a polyepitope antigen presentation system for reproducible expansion of antigen-specific T cells from immunocompetent and immunocompromised settings.     

Immune responses to vaccines involving a combined antigen–nanoparticle mixture and nanoparticle-encapsulated antigen formulation

Many physicochemical characteristics significantly influence the adjuvant effect of micro/nanoparticles; one critical factor is the kinetics of antigen exposure to the immune system by particle-adjuvanted vaccines. Here, we investigated how various antigen–nanoparticle formulations impacted antigen exposure to the immune system and the resultant antigen-specific immune responses. We formulated antigen with poly(lactic-co-glycolic acid) (PLGA) nanoparticles by encapsulating antigen within nanoparticles or by simply mixing soluble antigen with the nanoparticles. Our results indicated that the combined formulation (composed of antigen encapsulated in nanoparticles and antigen mixed with nanoparticles) induced more powerful antigen-specific immune responses than each single-component formulation. Mice immunized with the combined vaccine formulation displayed enhanced induction of antigen-specific IgG antibodies with high avidity, increased cytokine secretion by splenocytes, and improved generation of memory T cell. Enhanced immune responses elicited by the combined vaccine formulation might be attributed to the antigen-depot effect at the injection site, effective provision of both adequate initial antigen exposure and long-term antigen persistence, and efficient induction of dendritic cell (DC) activation and follicular helper T cell differentiation in draining lymph nodes. Understanding the effect of antigen–nanoparticle formulations on the resultant immune responses might have significant implications for rational vaccine design.     

A new flow cytometric assay for the simultaneous analysis of antigen-specific elimination of T cells in heterogenous T cell populations

Novel immunosuppressive strategies are targeting for an antigen-specific deletion of T cells responsible for organ damage in autoimmunity and allograft rejection. Here, we present a new flow cytometry-based assay that allows the reliable and efficient detection of T cells that were eliminated in an antigen-specific fashion. A stable cell-labelling technique utilizing the two membrane dyes PKH26 and PKH67 has been combined with annexin V and 7-aminoactinomycin (7-AAD) staining to detect apoptotic cells. A differential gating strategy enabled us to determine the viability/apoptosis for each PKH-stained T cell subpopulation independently. The capability to simultaneously analyze apoptosis within T cell mixtures of different antigen specificities establishes this assay as a superior tool for the further development of novel antigen-specific immunosuppressive approaches.     

Targeting antigen to CD19 on B cells efficiently activates T cells

CD19 is a B cell-surface molecule that participates as an important regulatory signaling complex for antigen bound at the surface by Ig. Triggering of CD19 through its linkage with CD21 amplifies signals transduced through the Src family kinases and modulates B cell differentiation in response to antigen. This study examines the kinetics of antigen uptake and processing of antigen directly targeted to the CD19 protein on purified B cells. We have demonstrated that the antigen internalized within minutes through CD19 forms a cap at the B cell surface and can be found within lysosomes in the cytoplasm in 90 min. B cells acquiring antigen via CD19 express elevated levels of B7-1 and B7-2 co-stimulatory molecules. Moreover, antigen-anti-CD19 complexes administered intravenously bind B cells in vivo and activate antigen-specific T cells more efficiently than non-specific uptake and in a manner similar to antigen taken up through surface IgM on B cells. This work illustrates an important and previously unrecognized mechanism for targeting proteins to B lymphocytes for antigen presentation and activation of CD4 T cells.     

Vaccine-induced antigen-specific regulatory T cells attenuate the antiviral immunity against acute influenza virus infection

Peptide-based T cell vaccines targeting the conserved epitopes of influenza virus can provide cross-protection against distantly related strains, but they are generally not immunogenic. Foreign antigen-specific regulatory T (Treg) cells are induced under subimmunogenic conditions peripherally, although their development and role in vaccine-mediated antiviral immunity is unclear. Here, we demonstrated primary vaccination with peptides alone significantly induced antigen-specific Foxp3⁺ Treg cells, which were further expanded by repeated vaccination with unadjuvanted peptides. Certain adjuvants, including CpG, suppressed the induction and expansion of antigen-specific Treg cells by peptide vaccination. Interestingly, secondary influenza virus infection significantly increased the frequency of preexisting antigen-specific Treg cells, although primary infection barely induced them. Importantly, specific depletion of vaccine-induced antigen-specific Treg cells promoted influenza viral clearance, indicating their inhibitory role in vivo. Immunization with CpG-adjuvanted peptides by the subcutaneous prime–intranasal-boost strategy restricted the recruitment and accumulation of antigen-specific Treg cells in lung, and stimulated robust T cell immunity. Finally, subcutaneous prime–intranasal-boost immunization with CpG-adjuvanted peptides or whole-inactivated influenza vaccines protected mice from heterosubtypic influenza virus infection. In conclusion, antigen-specific Treg cells induced by peptide vaccines attenuate the antiviral immunity against influenza virus infection. CpG-adjuvanted peptide vaccines provide heterosubtypic influenza protection probably by inhibiting Treg development and enhancing T cell immunity.     

Anti-OX40 stimulation in vivo enhances CD8+ memory T cell survival and significantly increases recall responses

There is growing evidence that engagement of OX40 (CD134), a member of the TNF receptor superfamily, can directly stimulate antigen-specific CD8+ T cells. It has been shown that CD8+ T cells express OX40 following activation, but the response of antigen-specific CD8+ T cells to OX40 stimulation has not been fully characterized. We utilized an antigen-specific transgenic CD8+ T cell model (OT-I) to determine if OX40 engagement can boost the generation of antigen-specific CD8+ T cell memory. Our results demonstrate that enhanced OX40 costimulation, via an agonist anti-OX40 antibody, increases CD25 and phospho-Akt expression on the antigen-specific CD8+ T cells and significantly increases the generation of long-lived antigen-specific CD8+ memory T cells. The increased numbers of memory CD8+ T cells generated via anti-OX40 treatment still required the presence of CD4+ T cells for their long-term maintenance in vivo. In addition, anti-OX40 costimulation greatly enhanced antigen-specific CD8+ T cell recall responses. These data show that OX40 engagement in vivo increases the number of antigen-specific CD8+ memory T cells surviving after antigen challenge and has implications for the development of more potent vaccines against pathogens and cancer.     

Drug nanocarriers to treat autoimmunity and chronic inflammatory diseases

Nanoparticles represent a new generation of drug delivery systems that can be engineered to harness optimal target selectivity for specific cells and tissues and high drug loading capacity, allowing for improved pharmacokinetics and enhanced bioavailability of therapeutics. The spontaneous propensity of both organic and colloidal nanoparticles to be captured by the cells of the reticuloendothelial system encouraged their utilization as passive targeting systems that can be preferentially directed to innate immune cells, such as macrophages, dendritic cells and neutrophils. The natural affinity for phagocytic cells suggests the possible implementation of nanoparticles as an immunotherapeutic platform for inflammatory diseases and autoimmune disorders. Here we discuss the recent advances in the application of nanotechnology to induce antigen-specific tolerance in autoimmunity and the use of nanoparticles for anti-inflammatory therapies, including treatment of inflammatory bowel diseases, psoriasis and rheumatoid arthritis.     

Cloned helper T cells can kill B lymphoma cells in the presence of specific antigen: Ia restriction and cognate vs. noncognate interactions in cytolysis

Cloned, Lyt-1+,2-, antigen-specific, Ia-restricted T cell lines can inhibit the growth of Ia-bearing B lymphoma cells in the presence of specific antigen. This effect is due to cytolysis of the B lymphoma cells in an antigen-specific, Ia-restricted manner by the cloned T cell lines. These cloned T cell lines can also kill lipopolysaccharide-activated normal B cells, while they activate resting B cells to divide and secrete immunoglobulin and are thus helper T cells as well as cytolytic T cells. The mechanism of cytolysis was examined in detail. Killing was mediated by a nonspecific mechanism after specific stimulation of the T cells with antigen presented in the context of the appropriate Ia glycoprotein complex, possibly implying a role for a soluble mediator. This simple system involving two clonal populations allows a detailed analysis of T-B interactions. Our studies are consistent with the view that both cognate and noncognate interactions of Ia-restricted T cells with B cells are mediated by nonspecific factors. Thus, the difference between interactions that appear to be cognate and those that appear to be noncognate may be quantitative rather than qualitative. That two cloned populations of cells can show either pattern of interaction depending on T-B ratio provides strong support for this view. Finally, that cloned helper T cells can kill activated B cells in an antigen-specific fashion may provide a new mechanism of immune regulation that would be especially important in responses to self antigens in vivo.     

Exploiting T cell receptor genes for cancer immunotherapy

Adoptive antigen-specific immunotherapy is an attractive concept for the treatment of cancer because it does not require immunocompetence of patients, and the specificity of transferred lymphocytes can be targeted against tumour-associated antigens that are poorly immunogenic and thus fail to effectively trigger autologous T cell responses. As the isolation and in vitro expansion of antigen-specific lymphocytes is difficult, 'conventional' adoptive T cell therapy can only be carried out in specialized centres in small numbers of patients. However, T cell receptor (TCR) genes isolated from antigen-specific T cells can be exploited as generic therapeutic molecules for 'unconventional' antigen-specific immunotherapy. Retroviral TCR gene transfer into patient T cells can readily produce populations of antigen-specific lymphocytes after a single round of polyclonal T cell stimulation. TCR gene modified lymphocytes are functionally competent in vitro, and can have therapeutic efficacy in murine models in vivo. TCR gene expression is stable and modified lymphocytes can develop into memory T cells. Introduction of TCR genes into CD8(+) and CD4(+) lymphocytes provides an opportunity to use the same TCR specificity to produce antigen-specific killer and helper T lymphocytes. Thus, TCR gene therapy provides an attractive strategy to develop antigen-specific immunotherapy with autologous lymphocytes as a generic treatment option.     

Antigen presentation by hapten-specific B lymphocytes. III. Analysis of the immunoglobulin-dependent pathway of antigen presentation to interleukin 1-dependent T lymphocytes

The ability of antigen-specific murine B lymphocytes to present antigen to a normal (nontransformed) antigen-specific, interleukin (IL)1-dependent T cell clone and to heterogeneous T lymphocytes was investigated. Hapten-specific lymphocytes present protein antigens to both the D10G.4.1 T cell clone and heterogeneous immune T cells. When the antigen bears an epitope recognized by the specific B cell, the subsequent presentation of this antigen is 10(2)-10(4)-fold more efficient, as compared to the same, but nonhaptenated protein. The requisite B lymphocyte binds hapten, is radiosensitive and is nonadherent to plastic. The hapten-specific antigen presentation is blocked by antibodies to the surface Ig receptor, while the presentation of unmodified protein is unaffected. These observations are identical to our findings in studies of B cell antigen presentation to T-T hybridomas and therefore demonstrate the generality of the immunoglobulin-dependent pathway of presentation. However, in contrast to the results with T-T hybridomas, the specific B lymphocytes are necessary, but not sufficient, to activate IL 1-dependent T cells. A third cell is required for both B lymphocyte immunoglobulin-dependent and nonspecific antigen-presentation. This cell is radioresistant, plastic adherent and of low density. The requirement for this third cell can be circumvented by supplementing cultures with highly purified IL 1. These results demonstrate that the remarkably efficient ability of B lymphocytes to present antigen is operative with factor-dependent T lymphocytes. Furthermore, conventional accessory cells also appear to play a role in this process, which is consistant with their known requirement in antigen-specific T-B interactions in the generation of antibody responses.     

DNA fusion gene vaccination mobilizes effective anti-leukemic cytotoxic T lymphocytes from a tolerized repertoire

The majority of known human tumor-associated antigens derive from non-mutated self proteins. T cell tolerance, essential to prevent autoimmunity, must therefore be cautiously circumvented to generate cytotoxic T cell responses against these targets. Our strategy uses DNA fusion vaccines to activate high levels of peptide-specific CTL. Key foreign sequences from tetanus toxin activate tolerance-breaking CD4(+) T cell help. Candidate MHC class I-binding tumor peptide sequences are fused to the C terminus for optimal processing and presentation. To model performance against a leukemia-associated antigen in a tolerized setting, we constructed a fusion vaccine encoding an immunodominant CTL epitope derived from Friend murine leukemia virus gag protein (FMuLV(gag)) and vaccinated tolerant FMuLV(gag)-transgenic (gag-Tg) mice. Vaccination with the construct induced epitope-specific IFN-gamma-producing CD8(+) T cells in normal and gag-Tg mice. The frequency and avidity of activated cells were reduced in gag-Tg mice, and no autoimmune injury resulted. However, these CD8(+) T cells did exhibit gag-specific cytotoxicity in vitro and in vivo. Also, epitope-specific CTL killed FBL-3 leukemia cells expressing endogenous FMuLV(gag) antigen and protected against leukemia challenge in vivo. These results demonstrate a simple strategy to engage anti-microbial T cell help to activate epitope-specific polyclonal CD8(+) T cell responses from a residual tolerized repertoire.     

T cell-mediated cognate signaling of nitric oxide production by macrophages. Requirements for macrophage activation by plasma membranes isolated from T cells

Macrophage generation of reactive nitrogen intermediates (RNI) represents a major effector mechanism in anti-microbial immunity and non-septic inflammatory reactions. The induction of macrophage RNI production has been demonstrated to require at least two signals which in microbial infections can be provided by interferon (IFN)-γ and lipopolysaccharide (LPS). The current study demonstrates that, in the absence of LPS, T lymphocytes can provide cognate signal(s) which synergize with IFN-γ in stimulating macrophage RNI production, as evidenced by the ability of plasma membranes from T cell clones to activate IFN-γ-primed macrophages. Although viable resting T cells can activate IFN-γ-primed macrophages by an interaction that is antigen specific, plasma membranes from resting T cells do not activate macrophages. Plasma membranes from T cells activated by immobilized anti-CD3 were able to effectively induce RNI production in IFN-γ-primed macrophages. However, in contrast to the antigen-specific interaction of macrophages with viable resting T cells, the activation of IFN-γ-primed macrophages by membranes from activated T cells does not display antigen specificity. Plasma membranes from activated T helper T_H2 and from activated T_H1 cells were equally effective in activating IFN-γ-primed macrophages, suggesting that the dominance of T_H1 over TH2 cells in cell-mediated responses involving macrophage effectors is not a reflection of differences in their ability to interact with macrophages but rather is a reflection of their different pattern of cytokine production. These results suggest that the T cell-macrophage interaction involves reciprocal activation of both cells - an antigen-specific activation of the T cells which results in the acquisition of T cell membrane components involved in antigen-nonspecific stimulation of the macrophages.     

Ex vivo induction of viral antigen-specific CD8 T cell responses using mRNA-electroporated CD40-activated B cells

Cell-based immunotherapy, in which antigen-loaded antigen-presenting cells (APC) are used to elicit T cell responses, has become part of the search for alternative cancer and infectious disease treatments. Here, we report on the feasibility of using mRNA-electroporated CD40-activated B cells (CD40-B cells) as alternative APC for the ex vivo induction of antigen-specific CD8(+) T cell responses. The potential of CD40-B cells as APC is reflected in their phenotypic analysis, showing a polyclonal, strongly activated B cell population with high expression of MHC and co-stimulatory molecules. Flow cytometric analysis of EGFP expression 24 h after EGFP mRNA-electroporation showed that CD40-B cells can be RNA transfected with high gene transfer efficiency. No difference in transfection efficiency or postelectroporation viability was observed between CD40-B cells and monocyte-derived dendritic cells (DC). Our first series of experiments show clearly that peptide-pulsed CD40-B cells are able to (re)activate both CD8+ and CD4(+) T cells against influenza and cytomegalovirus (CMV) antigens. To demonstrate the ability of viral antigen mRNA-electroporated CD40-B cells to induce virus-specific CD8+ T cell responses, these antigen-loaded cells were co-cultured in vitro with autologous peripheral blood mononuclear cells (PBMC) for 7 days followed by analysis of T cell antigen-specificity. These experiments show that CD40-B cells electroporated with influenza M1 mRNA or with CMV pp65 mRNA are able to activate antigen-specific interferon (IFN)-gamma-producing CD8(+) T cells. These findings demonstrate that mRNA-electroporated CD40-B cells can be used as alternative APC for the induction of antigen-specific (memory) CD8(+) T cell responses, which might overcome some of the drawbacks inherent to DC immunotherapy protocols.