肿瘤?鄄树突状细胞融合疫苗研究进展

树突状细胞(DC)是功能最强的专职抗原呈递细胞,在抗肿瘤免疫方面发挥着重要的作用．以DC为基础的肿瘤疫苗的研究发展迅速,其中效果最好的是DC/肿瘤融合细胞疫苗——不仅具有DC的抗原呈递功能,也持续产生内源性抗原肽．DC/肿瘤融合细胞疫苗不仅在动物实验中进行了大量的研究,而且已经进入了Ⅰ/Ⅱ期临床试验,结果表明,融合细胞能有效地诱导肿瘤特异性T淋巴细胞反应,病人也能很好地耐受．就DC/肿瘤融合疫苗的研究进展进行综述,并对目前研究中存在的问题作了客观的分析．     

肿瘤抗原基因转染的DC疫苗研究进展

树突状细胞是机体内最重要、功能最强的专职抗原递呈细胞,是抗肿瘤免疫的最好佐剂。将不同形式肿瘤抗原负载的DC制成疫苗,可以在体内诱导特异性杀伤性T细胞（CTL）的生成,激发人体有效的特异性抗肿瘤免疫功能。其中肿瘤抗原原因转当的DC疫苗具有很多独特的优点,可望作为一种新型肿瘤疫苗用于肿瘤的防治。本文主要就其作用特点、体内应用的可行性及抗肿瘤作用效果的实验研究进展等方面作一综述。     

p53转染黑色素瘤细胞修饰的树突状细胞疫苗体外抗肿瘤作用的研究

利用野生型p53质粒转染黑色素瘤B16细胞,反复冻融法提取p53修饰的肿瘤抗原(p53-Ag),将抗原体外冲击同基因小鼠骨髓来源的树突状细胞(dendritic cells,DC)制备特异性DC肿瘤疫苗;观察DC诱导的淋巴细胞增殖反应和细胞毒性T淋巴细胞(cytotoxic T lymphocytes,CTL)对黑色素瘤细胞的细胞毒效应,分析其诱导肿瘤抗原特异性免疫应答的机制。结果显示,p53-肿瘤抗原冲击的DC可显著刺激淋巴细胞增殖,其诱导的CTL效应对肿瘤细胞也有很好的杀伤效果。     

结核病疫苗研究进展

随着对抗结核免疫机制的深入研究,新型结核疫苗的研发也更加理性和成熟。近期研究表明,CD4 T细胞多功能至关重要,人类CD8和γδT细胞也有抗结核免疫保护作用,是新型疫苗设计有潜力的T细胞靶点。系统的"组学"技术大规模筛选有可能发现更多强免疫原性的抗原。不同表达时期的多抗原组成的多价疫苗对不同感染时期的结核都有预防作用。针对潜伏感染或已经感染个体配合化学药物使用的新型治疗性疫苗,有望促进清除残留的结核分枝杆菌。     

枸杞多糖调控口蹄疫重组腺病毒疫苗诱导DC及T细胞亚群的研究

近年来,随着许多病毒性疾病的发展,社会对于新型疫苗的研发迫在眉睫。与传统疫苗相比,新型疫苗具有安全可靠的优点,但其免疫原性较弱的特点也十分突出,因此,研究出安全稳定有效的免疫调节剂来增强疫苗的免疫效果成为研究学者们共同的关注点。枸杞是传统的名贵补益中药,枸杞多糖(Lycium barbarum polysaccharide,LBP)是其中的主要生物活性成分,具有免疫调节、抗肿瘤、抗衰老等多种生物学作用。本研究通过体内实验观察LBP对口蹄疫重组腺病毒疫苗(rAd5VP1)诱导小鼠脾脏树突状细胞(Dendritic cells,DC)成熟、辅助性T细胞1(T helper cells 1,Th1)、辅助性T细胞2(T helper cells 2,Th2)、滤泡辅助性T细胞(T follicular helper cells,Tfh)及调节性T细胞(Regulatory T cells,Treg)分化的免疫调节作用,为阐明LBP免疫调节的新机制提供实验依据。6周龄的雌性BALB/c小鼠随机分为5组,每组5只,所有小鼠均行腹腔注射rAd5VP1,同时分别给予低剂量(10mg/kg·d)、中剂量(20mg/kg·d)、高剂量(40mg/kg·d)的LBP,阴性对照组和阳性对照组分别给予磷酸盐缓冲液(Phosphate buffer solution,PBS)和脂多糖(Lipopolysaccharide,LPS)(1mg/kg·d)。免疫7d后,应用流式细胞术(Flow cytometry,FCM)检测小鼠脾脏DC(CD11c+MHCⅡ+CD86+)、Th1细胞(CD4+IFN-γ+)、Th2细胞(CD4+IL-4+)、Tfh细胞(CD4+CXCR5+)及Treg细胞(CD4+CD25+FoxP3+)的数量与比例。结果表明,与PBS组相比,LBP能明显诱导DC的成熟,DC表面的共刺激分子CD86的表达量明显升高;LBP能明显促进Th2细胞、Tfh细胞的分化,LBP对Th1细胞的分化无明显影响,LBP能抑制Treg细胞的分化。本研究证实LBP作为疫苗免疫调节剂,可调控DC及Th细胞亚群的分化而发挥免疫调节作用,为LBP的免疫调节机制提供理论依据。     

CD137^(+)T细胞效应功能研究进展

CD137^(+)(又称4-1BB、TNFRSF9)T细胞亚群是一类抗原特异性活化的效应细胞。CD137^(+)T细胞产生细胞毒效应因子以及在抗原刺激后进行增殖的能力较强,使其在多种疾病中发挥免疫调节作用,其中CD137^(+)调节性T细胞分泌的分泌型CD137具有重要的免疫抑制作用。因此,全面了解CD137^(+)T细胞在疾病中的作用,对开发有效的疾病免疫防治策略至关重要。本文通过介绍CD137相关信号对T细胞尤其是CD8^(+)T细胞功能的调控机制、CD137^(+)T细胞的特征和效应功能、CD137^(+)T细胞在多种疾病进展中的免疫调控作用,为靶向CD137^(+)T细胞的免疫治疗提供参考。     

结核杆菌感染T细胞介导免疫应答研究的新进展

结核病对免疫学家构成了巨大的挑战,因为它是一种慢性传染性疾病,病原体具有持久性特点.在对人和动物进行实验时,检测到结核分枝杆菌适应性免疫应答的特点之一为感染早期T细胞免疫应答延迟.新近研究揭示了此种延迟应答的机制:通过结核杆菌抑制免疫细胞(CD4+和CD8+T细胞及DC)凋亡延迟应答,通过特异性Treg细胞抑制作用延迟应答.结核杆菌慢性感染期间存在IFNγ信号调节网络和ESAT-6抗原的慢性刺激作用,抗原特异性PD-1+ CD4+T细胞具有高度增殖分化为更多终末效应性T细胞的潜能,以此可调节和维持免疫应答.深入了解抗原特异性T细胞调节与维持适应性免疫应答的机制,有益于抗结核疫苗的设计和研制.     

T细胞免疫在抗结核杆菌感染中的研究进展

结核分枝杆菌是引起结核病的病原体,该细菌可侵犯全身各组织器官。结核病是一种慢性传染性疾病,具有持久性特点。该细菌为胞内寄生菌,特异性免疫以细胞免疫为主,主要包括CD4＋T细胞免疫和CD8＋T细胞免疫。结核分枝杆菌特异性免疫应答的特点之一是感染早期T细胞免疫应答延迟。其机制与结核杆菌抑制免疫细胞（CD4＋和CD8＋T细胞及DC）凋亡延迟应答,通过特异性Treg细胞抑制作用延迟应答以及结核杆菌慢性感染期间存在IFN-γ信号调节网络和ESAT-6抗原的慢性刺激作用有关,以此可调节和维持免疫应答。深入了解抗原特异性T细胞特异性免疫应答的机制,有益于抗结核疫苗的研制,为临床工作提供理论依据和科学方法。     

T细胞免疫在抗结核杆菌感染中的研究进展

结核分枝杆菌是引起结核病的病原体,该细菌可侵犯全身各组织器官。结核病是一种慢性传染性疾病,具有持久性特点。该细菌为胞内寄生菌,特异性免疫以细胞免疫为主,主要包括CD4+T细胞免疫和CD8+T细胞免疫。结核分枝杆菌特异性免疫应答的特点之一是感染早期T细胞免疫应答延迟。其机制与结核杆菌抑制免疫细胞(CD4+和CD8+T细胞及DC)凋亡延迟应答,通过特异性Treg细胞抑制作用延迟应答以及结核杆菌慢性感染期间存在IFN-γ信号调节网络和ESAT-6抗原的慢性刺激作用有关,以此可调节和维持免疫应答。深入了解抗原特异性T细胞特异性免疫应答的机制,有益于抗结核疫苗的研制,为临床工作提供理论依据和科学方法。     

表达丙型肝炎病毒(HCV)截短型NS3与core融合抗原的重组腺病毒疫苗在小鼠中的免疫原性与保护效果分析

为研发安全广谱有效的丙型肝炎病毒(Hepatitis C virus,HCV)T细胞疫苗,本研究构建了表达HCV截短型非结构蛋白3(Nonstructural protein 3,NS3)与核心蛋白(core)融合抗原的重组腺病毒疫苗。体外免疫荧光及蛋白印迹实验表明该融合抗原可有效表达;小鼠免疫结果表明该重组腺病毒疫苗除了激发抗原特异的抗体反应外,还可激发较强的针对NS3抗原特异的T细胞免疫应答。该T细胞免疫应答主要表现为IFN-γ+与TNF-α+CD4+T细胞亚群。采用异型(JFH1,2a型)HCV重组痘病毒接种小鼠进行保护效果分析,与对照组相比,表达截短型NS3与core融合抗原的重组腺病毒疫苗2针免疫后可产生明显的交叉免疫保护。本研究为进一步研究HCV免疫保护机制及新型疫苗研制提供了参考。     

The role of Th17 cytokines in primary mucosal immunity

The T helper type 17 (Th17) lineage of CD4+ T-cells produce several effector molecules including IL-17A, IL-17F, IL-21, and IL-22. In addition to CD4+, αβ T-cells, these cytokines can be produced by natural killer and γδ T-cells. These effector cytokines can be produced rapidly upon infection at mucosal sites and evidence to date strongly implicates that this arm of the immune system plays a critical role in mucosal immunity to many extracellular pathogens. Moreover these cytokines can also coordinate adaptive immunity to some intracellular pathogens. In this review, we will highlight recent progress in our understanding of these cytokines, and mechanisms of their effector function in the mucosa.     

Immune response to pre-erythrocytic stages of malaria parasites

Immunization with radiation-attenuated Plasmodium spp. sporozoites induces sterile protective immunity against parasite challenge. This immunity is targeted primarily against the intrahepatic parasite and appears to be sustained long term even in the absence of sporozoite exposure. It is mediated by multifactorial mechanisms, including T cells directed against parasite antigens expressed in the liver stage of the parasite life cycle and antibodies directed against sporozoite surface proteins. In rodent models, CD8+ T cells have been implicated as the principal effector cells, and IFN-gamma as a critical effector molecule. IL-4 secreting CD4+ T cells are required for induction of the CD8+ T cell responses, and Th1 CD4+ T cells provide help for optimal CD8+ T cell effector activity. Components of the innate immune system, including gamma-delta T cells, natural killer cells and natural killer T cells, also play a role. The precise nature of pre-erythrocytic stage immunity in humans, including the contribution of these immune responses to the age-dependent immunity naturally acquired by residents of malaria endemic areas, is still poorly defined. The importance of immune effector targets at the pre-erythrocytic stage of the parasite life cycle is highlighted by the fact that infection-blocking immunity in humans rarely, if ever, occurs under natural conditions. Herein, we review our current understanding of the molecular and cellular aspects of pre-erythrocytic stage immunity.     

Differential DNA damage induced by H2O2 and bleomycin in subpopulations of human white blood cells

The purpose of this study was to characterize the differential sensitivities of various subpopulations of human white blood cells after exposure to H2O2 (an oxidant agent) and bleomycin (a radiomimetic glycopeptide), in vitro, using single-cell gel electrophoresis (SCGE). Human peripheral blood was fractionated into mononuclear cells, which were further separated into monocytes, CD4+ T-cells, CD8+ T-cells, B-cells and natural killer cells (NK cells). The separated fractions were exposed to different doses of H2O2 and bleomycin, and then used to measure levels of induced and basal DNA damage. There was a significant increase in the amount of DNA damage in CD4+ T-cells, CD8+ T-cells, NK cells and B-cells when treated with H2O2 and bleomycin, whereas monocytes had the lowest sensitivity to H2O2 compared with the other cell fractions, but no lower sensitivity to bleomycin. Furthermore, CD4+ T-cells and CD8+ T-cells had the highest levels of basal DNA damage. When basal DNA damage was taken into account, NK cells tended to show a higher sensitivity to H2O2 than CD4+ T-cells, CD8+ T-cells and monocytes. In addition, B-cells, which showed lower sensitivity to H2O2 than CD4+ T-cells, CD8+ T-cells and NK cells when exposed to lower doses of H2O2 (<10 microM), showed higher sensitivity to H2O2 at higher doses (>20 microM). On the other hand, B-cells showed the highest sensitivity to bleomycin.     

Skin TLR7 Triggering Promotes Accumulation of Respiratory Dendritic Cells and Natural Killer Cells

The TLR7 agonist imiquimod has been used successfully as adjuvant for skin treatment of virus-associated warts and basal cell carcinoma. The effects of skin TLR7 triggering on respiratory leukocyte populations are unknown. In a placebo-controlled experimental animal study we have used multicolour flow cytometry to systematically analyze the modulation of respiratory leukocyte subsets after skin administration of imiquimod. Compared to placebo, skin administration of imiquimod significantly increased respiratory dendritic cells (DC) and natural killer cells, whereas total respiratory leukocyte, alveolar macrophages, classical CD4+ T helper and CD8+ T killer cell numbers were not or only moderately affected. DC subpopulation analyses revealed that elevation of respiratory DC was caused by an increase of respiratory monocytic DC and CD11b(hi) DC subsets. Lymphocyte subpopulation analyses indicated a marked elevation of respiratory natural killer cells and a significant reduction of B lymphocytes. Analysis of cytokine responses of respiratory leukocytes after stimulation with Klebsiella pneumonia indicated reduced IFN-γ and TNF-α expression and increased IL-10 and IL-12p70 production after 7 day low dose skin TLR7 triggering. Additionally, respiratory NK cytotoxic activity was increased after 7d skin TLR7 triggering. In contrast, lung histology and bronchoalveolar cell counts were not affected suggesting that skin TLR7 stimulation modulated respiratory leukocyte composition without inducing overt pulmonary inflammation. These data suggest the possibility to modulate respiratory leukocyte composition and respiratory cytokine responses against pathogens like Klebsiella pneumonia through skin administration of a clinically approved TLR7 ligand. Skin administration of synthetic TLR7 ligands may represent a novel, noninvasive means to modulate respiratory immunity.     

Differential mobilization of leucocyte and lymphocyte subpopulations into the circulation during endurance exercise.

A total of 14 healthy subjects [means (SD): 27.6 (3.8) years; body mass 77.8 (6.6) kg; height 183 (6) cm] performed endurance exercise to exhaustion at 100% of the individual anaerobic threshold (Th(an)) on a cycle ergometer (mean workload 207 (55) W; lactate concentrations 3.4 (1.2) mmol.l-1; duration 83.8 (22.2) min, including 5 min at 50% of individual Th(an)). Leucocyte subpopulations were measured by flow cytometry and catecholamines by radioimmunological methods. Blood samples were taken before and several times during exercise. Values were corrected for plasma volume changes and analysed using ANOVA for repeated measures. During the first 10 min of exercise, of all cell subpopulations the natural killer cells (CD3-CD16/CD56+) increased the most (229%). Also CD3+CD16/CD56+ (84%), CD8+CD45RO- (69%) cells, eosinophils (36%) and monocytes (62%) increased rapidly during that time. CD3+, CD3+HLA-DR+, CD4+CD45RO+, CD4+CD45RO-, CD8+CD45RO+ and CD19+ cells either did not increase or increased only slightly during exercise. Adrenaline and noradrenaline increased nearly linearly by 36% and 77% respectively at 10 min exercise. The increase of natural killer cells and heart rates between rest and 10 min of exercise correlated significantly (r = 0.576, P = 0.031). We conclude that natural killer cells, cytotoxic, non-MHC-restricted T-cells, monocytes and eosinophils are mobilized rapidly during the first minutes of endurance exercise. Both catecholamines and increased blood flow are likely to contribute this effect.     

Intermediate maturation of Mycobacterium tuberculosis LAM-activated human dendritic cells

Contrasting observations raise the question of the role of mycobacterial derived products as compared with the whole bacterium Mycobacterium tuberculosis on maturation and function of human dendritic cells (DCs). DC-SIGN has been identified as the key DC receptor for M. tuberculosis through its interaction with the mannosylated lipoarabinomannan (ManLAM). Although ManLAM is a major mycobacterial component released from infected antigen-presenting cells, there is no formal evidence yet for an effect of ManLAM per se on DC maturation and function. DCs activated with purified ManLAM displayed an intermediate maturation phenotype as compared with lipopolysaccharide fully matured DCs with reduced expression of MHC class I and class II molecules, CD83 and CD86 and of the chemokine receptor CCR7. They were sensitive to autologous natural killer (NK) lysis, thus behaving like immature DCs. However, ManLAM-activated DCs lost phagocytic activity and triggered priming of naive T-cells, confirming their intermediate maturation. Partial maturation of ManLAM-activated DCs was overcome by triggering the CD40/CD40L pathway as a second signal, which completed maturation phenotypically and abolished autologous NK lysis susceptibility. Altogether, these data provide evidence that ManLAM may induce a partial maturation phenotype on non-infected bystander DCs during infection suggesting that ManLAM released from infected cells might impair adaptive immune response towards M. tuberculosis.     

Production of biologically active human lymphotactin (XCL1) by <Emphasis Type="Italic">Lactococcus lactis</Emphasis>

Lymphotactin-XCL1 is a chemokine produced mainly by activated CD8+ T-cells and directs migration of CD4+ and CD8+ lymphocytes and natural killer (NK) cells. We expressed human lymphotactin (LTN) by the lactic-acid bacterium Lactococcus lactis. Biological activity of LTN was confirmed by chemo-attraction of human T-cells by chemotaxis demonstrating, for the first time, how this chemokine secreted by a food-grade prokaryote retains biological activity and chemoattracts T lymphocytes. This strain thus represents a feasible well-tolerated vector to deliver active LTN at a mucosal level. Laura M. Zavala-Flores and Julio Villatoro-Hernandez have contributed equally to this work.     

Dendritic cells of mucosa and skin: "recruited for vaccination"

Mucosae and skin are exposed to environmental antigens and are natural entry routes for most infectious agents. To maintain immunological tolerance and ensure protective immunity against pathogens, epithelial surfaces are surveyed permanently by antigen-presenting dendritic cells (DCs). Many DC subsets have been described in epithelial tissues, depending on the inflammatory state and the type of epithelium. Identification of the DC subset able to induce cytotoxic CD8+ T cells against antigens delivered via mucosae or skin, is a major issue for the development of efficient anti-infectious and anti-tumoral vaccines. Until recently, it was commonly accepted that Langerhans cells (LC), the prototype of immature DCs residing in skin and certain mucosae, can capture and process antigens and, in response to danger signals, undergo a maturation program allowing their migration to the draining lymph nodes for priming of na?ve T cells. This concept likely needs to be revisited. Recent evidence from animal models revealed that resident epithelial tissue DCs, including LCs, do not play a direct role in T cell priming, but may contribute to maintenance of peripheral tolerance. Alternatively, DCs newly recruited into muco-cutaneous tissues exposed to pro-inflammatory stimuli are responsible for efficient priming and differentiation of CD8+ T cells into cytolytic effectors. These DC originate from blood monocytes and can cross-present protein antigens to CD8+ T cells, which subsequently give rise to specific CTL effectors. Remarkably, components derived from bacteria, virus and chemicals capable to enhance CCL20 production in epithelia, promote CCR6-dependent DC recruitment and behave as adjuvants allowing for cross-primed CD8+ CTL. These advances in the dynamic and function of epithelial tissue DC provide a rationale for the screening of novel CD8+ T cell adjuvants and the design of novel mucosal and skin vaccines.     

CD80 and CD86 Differentially Regulate Mechanical Interactions of T-Cells with Antigen-Presenting Dendritic Cells and B-Cells

Functional T-cell responses are initiated by physical interactions between T-cells and antigen-presenting cells (APCs), including dendritic cells (DCs) and B-cells. T-cells are activated more effectively by DCs than by B-cells, but little is known about the key molecular mechanisms that underpin the particular potency of DC in triggering T-cell responses. To better understand the influence of physical intercellular interactions on APC efficacy in activating T-cells, we used single cell force spectroscopy to characterize and compare the mechanical forces of interactions between DC:T-cells and B:T-cells. Following antigen stimulation, intercellular interactions of DC:T-cell conjugates were stronger than B:T-cell interactions. DCs induced higher levels of T-cell calcium mobilization and production of IL-2 and IFNγ than were elicited by B-cells, thus suggesting that tight intercellular contacts are important in providing mechanically stable environment to initiate T-cell activation. Blocking antibodies targeting surface co-stimulatory molecules CD80 or CD86 weakened intercellular interactions and dampen T-cell activation, highlighting the amplificatory roles of CD80/86 in regulating APC:T-cell interactions and T-cell functional activation. The variable strength of mechanical forces between DC:T-cells and B:T-cell interactions were not solely dependent on differential APC expression of CD80/86, since DCs were superior to B-cells in promoting strong interactions with T-cells even when CD80 and CD86 were inhibited. These data provide mechanical insights into the effects of co-stimulatory molecules in regulating APC:T-cell interactions.     

Enhanced anti-tumor immunity by superantigen-pulsed dendritic cells

Staphylococcal enterotoxins A (SEA) and B (SEB) are classical models of superantigens (SAg), which induce potent T-cell-stimulating activity by forming complexes with MHC class II molecules on antigen-presenting cells. This large-scale activation of T-cells is accompanied by increased production of cytokines such as interferon-γ (IFN-γ). Additionally, as we previously reported, IFN-γ-producing CD8(+) T cells act as "helper cells," supporting the ability of dendritic cells to produce interleukin-12 (IL-12)p70. Here, we show that DC pulsed with SAg promote the enhancement of anti-tumor immunity. Murine bone marrow-derived dendritic cells (DC) were pulsed with OVA(257-264) (SIINFEKL), which is an H-2Kb target epitope of EG7 [ovalbumin (OVA)-expressing EL4] cell lines, in the presence of SEA and SEB and were subcutaneously injected into na?ve C57BL/6 mice. SAg plus OVA(257-264)-pulsed DC vaccine strongly enhanced peptide-specific CD8(+) T cells exhibiting OVA(257-264)-specific cytotoxic activity and IFN-γ production, leading to the induction of protective immunity against EG7 tumors. Furthermore, cyclophosphamide (CY) added to SAg plus tumor-antigens (OVA(257-264), tumor lysate, or TRP-2) pulsed DC immunization markedly enhanced tumor-specific T-cell expansion and had a significant therapeutic effect against various tumors (EG7, 2LL, and B16). Superantigens are potential candidates for enhancing tumor immunity in DC vaccines.