浆细胞样树突状细胞与免疫耐受

浆细胞样树突状细胞(PDC)来源于淋巴系干细胞,其表面标志、功能有别于髓系DC,不仅在抗病毒免疫中发挥重要作用,而且通过多种途径诱导T细胞失能和调节性T细胞的形成,从而参与免疫耐受的诱导.PDC诱导T细胞免疫耐受的分子机制与吲哚胺2,3-双加氧酶(IDO)-色氨酸代谢通路和具有抑制功能的膜分子密切相关.深入阐明PDC诱导耐受的机制,将为免疫耐受异常相关的疾病的治疗提供新方案.     

Tumor's other immune targets: dendritic cells.

The induction of apoptosis in T cells is one of several mechanisms by which tumors escape immune recognition. We have investigated whether tumors induce apoptosis in dendritic cells (DC) by co-culture of murine or human DC with different tumor cell lines for 4-48 h. Analysis of DC morphological features, JAM assay, TUNEL, caspase-3-like and transglutaminase activity, Annexin V binding, and DNA fragmentation assays revealed a time- and dose-dependent induction of apoptosis in DC by tumor-derived factors. This finding is both effector and target specific. The mechanism of tumor-induced DC apoptosis involved regulation of Bcl-2 and Bax expression. Double staining of both murine and human tumor tissues confirmed that tumor-associated DC undergo apoptotic death in vivo. DC isolated from tumor tissue showed significantly higher levels of apoptosis as determined by TUNEL assay when compared with DC isolated from spleen. These findings demonstrate that tumors induce apoptosis in DC and suggest a new mechanism of tumor escape from immune recognition. DC protection from apoptosis will lead to improvement of DC-based immunotherapies for cancer and other immune diseases.     

Lung dendritic cells at the innate-adaptive immune interface

This review updates the basic biology of lung DCs and their functions. Lung DCs have taken center stage as cellular therapeutic targets in new vaccine strategies for the treatment of diverse human disorders, including asthma, allergic lung inflammation, lung cancer, and infectious lung disease. The anatomical distribution of lung DCs, as well as the division of labor between their subsets, aids their ability to recognize and endocytose foreign substances and to process antigens. DCs can induce tolerance in or activate na?ve T cells, making lung DCs well-suited to their role as lung sentinels. Lung DCs serve as a functional signaling/sensing unit to maintain lung homeostasis and orchestrate host responses to benign and harmful foreign substances.     

CD83 expression on dendritic cells and T cells: correlation with effective immune responses

Human CD83 is a marker molecule for mature dendritic cells (DC) and is also expressed on activated B and T cells. Although CD83 has been implicated in immune responses, its function on DC and T cells remains unclear. In this study, we wanted to assess the role of CD83 expressed on DC and T cells in the immune response. Down-regulation of CD83 expression on human DC through RNA interference (RNAi) results in a less potent induction of allogeneic T cell proliferation, reduced IFN-gamma secretion by established T cells and decreased capacity in the priming of functional tumor antigen-specific CD8+ T lymphocytes. In addition, CD83 mRNA-electroporated DC are stronger T cell stimulators. However, CD83 overexpression on Melan-A/MART-1-specific tumor-infiltrating lymphocytes (TIL) circumvents the need for CD83 expression on DC. Co-culture of immature DC with TIL or K562 cells overexpressing CD83 results in the production of enhanced levels of pro-inflammatory cytokines, whereas this production is less pronounced or even absent in co-cultures with non-modified TIL or K562 cells. In conclusion, we demonstrate that CD83 expression on T cells and DC modulates the immune response by activating DC and by delivering costimulatory signals for the stimulation of naive and memory T cells, respectively.     

Shaping the immune response to parasites: role of dendritic cells

Parasites represent a diverse group of pathogens that often trigger highly polarized immune responses that become tightly regulated during chronic infection. Recent studies have implicated the parasite-dendritic-cell interaction as a key determinant of the host response to these eukaryotic invaders. Dendritic cells appear to be pivotal in the initiation of cellular immunity against parasites as well as in directing Th1/Th2 effector choice. Moreover, there is increasing evidence that parasites regulate dendritic-cell function for the purposes of evading host immunity. This regulation also benefits parasites by protecting their host niche from the potentially lethal consequences of an uncontrolled inflammatory response.     

迁移性树突状细胞与淋巴结内树突状细胞在抗B.suis免疫应答中的作用

目的:研究迁移性树突状细胞与淋巴结内树突状细胞在抗猪布鲁氏菌免疫应答中的作用。方法:48只BALB/c小鼠随机分为3组:Ⅰ组为正常对照组,阴道滴注PBS;Ⅱ组为巨噬细胞(Mφ)清除组,每只小鼠阴道滴入清除剂;Ⅲ组为未清除Mφ组,每只小鼠阴道滴注同体积的liposome-PBS;48小时后Ⅱ组、Ⅲ组均阴道接种猪布鲁氏菌,对照组阴道滴注PBS。各组小鼠分别在接种12、24、48和72小时采集血液和髂内淋巴结,采用免疫组织化学染色法观察淋巴结内树突状细胞(DC)的分布,用ELISA法检测血清中IFN-γ和IL-4的含量。结果:未清除Mφ组小鼠接种布鲁氏菌后髂内淋巴结内有大量DC迁移,至12小时血清IFN-γ水平显著增高,与对照组相比差异显著(P0.05),48小时达到高峰,显著高于对照组(P0.01)。清除Mφ组小鼠接种布鲁氏菌后,髂内淋巴结内没有明显的DC迁移,各时间点血清IFN-γ水平明显高于PBS对照组(P0.05),但明显低于未清除Mφ组(P0.05)。各组IL-4水平的差异无统计学意义(P0.05)。结论:迁移性DC和淋巴结内DC在启动抗布鲁氏菌细胞免疫应答中均发挥重要作用,并具有协同作用的特点。     

浆细胞样树突状细胞在感染性、免疫性疾病中的研究进展

浆细胞样树突状细胞（PDC）来源于淋巴系造血干／祖细胞,能选择性的诱导免疫应答,并在一定条件下诱导免疫耐受,在抗病毒感染中起重要作用,并可能参与了某些自身免疫性疾病的发生。PDC产生的Ⅰ型IFN（IFN-α／β）在抗病毒过程中很关键,而一定条件下PDC诱导的免疫耐受与调节性T细胞的产生相关。自身免疫性疾病中持续高水平的Ⅰ型IFN提示PDC可能参与此类疾病的发病机制。     

Modulating the immune response with dendritic cells and their growth factors

Different subsets of dendritic cells (DCs) appear to play a role in determining the specific cytokines secreted by T helper (Th) cells. A model is proposed that links together factors such as the pathogen, microenvironment, DCs and T cells in a mechanism that results in a flexible determination of T-cell polarization.     

Cutaneous leishmaniasis: Distinct functions of dendritic cells and macrophages in the interaction of the host immune system with Leishmania major

Leishmaniasis is transmitted by sand flies leading to parasite inoculation into skin. In the mammalian host, the parasite primarily resides in skin macrophages (MΦ) and dendritic cells (DC). MΦ are silently invaded by the parasite eliciting a stress response, whereas DC become activated, release IL-12, and prime antigen-specific T cells. Here we review the basics of the immune response against this human pathogen and elucidate the role and function DC and MΦ for establishment of protective immunity against leishmaniasis. We focus on cell type-specific differences in parasite uptake, phagocyte activation and processing of parasite antigens to facilitate an understanding how their respective function may be modulated e.g. under therapeutic considerations.     

TCRγδ cells: Mysterious cells of the immune system

γδ cells participate in pathogenic infections and autoimmune conditions, yet, almost a decade after their discovery, little is known regarding their TCR repertoire or effector functions. Unlike MHC-restricted antigen recognition employed by TCRαβ cells, TCRγδ cells can recognize whole unprocessed antigens in an MHC-independent manner. The nature of positive and negative selection used to shape the repertoire of TCRγδ cells is unclear, especially in the nonlymphoid tissues where these cells predominate. While TCRγδ cells express an activated phenotype and are present in pathological conditions, their roles in immunological protection is unknown. This review will focus on our efforts to study these issues of TCRγδ biology.     

The current immune function of hepatic dendritic cells

While only a small percentage of the liver as dendritic cells, they play a major role in the regulation of liver immunity. Four major types of dendritic cell subsets include myeloid CD8α^-B220^-, lymphoid CD8α^＋B220^-, plasmacytoid CD8α^-B220^＋, and natural killer dendritic cell with CD8α^-B220^-NK1.1^＋ phenotype. Although these subsets have slightly different characteristics, they are all poor naive T cell stimulators. In exchange for their reduced capacity for allostimulation, hepatic DCs are equipped with an enhanced ability to secrete cytokines in response to TLR stimulation. In addition, they have increased level of phagocytosis. Both of these traits suggest hepatic DC as part of the innate immune system. With such a high rate of exposure to the dietary and commensal antigens, it is important for the hepatic DCs to have an enhanced innate response while maintaining a tolerogenic state to avoid chronic inflammation. Only upon secondary infectivity does the hepatic DC activate memory T cells for rapid eradication of recurring pathogen. On the other hand, overly tolerogenic characteristics of hepatic DC may be responsible for the increase prevalence of autoimmunity or liver malignancies.     

The brain as an immune privileged site: dendritic cells of the central nervous system inhibit T cell activation

Dendritic cells (DC) are unique in their ability to prime naive T cells and initiate adaptive immunity. In recent years, DC were identified in the inflamed central nervous system (CNS), but their role in the initiation or regulation of the tissue specific immune response is unknown. As shown here, DC isolated from mice with experimental autoimmune encephalomyelitis (EAE) exhibit a maturational phenotype similar to immature bone marrow-derived DC or splenic DC as characterized by intermediate surface MHC class II and low expression of the costimulatory molecule CD80. However, they are unable to prime naive T cells. Moreover, they inhibit T cell proliferation stimulated by mature bone marrow-derived DC. TGFbeta, IL-10 and TRAIL were found to significantly contribute to the CNS-DC-mediated inhibition of allo-T cell proliferation. Thus CNS-DC may be the key responsibles for maintaining immune privilege within the inflamed CNS.     

Artificially generated dendritic cells misdirect antiviral immune responses

Dendritic cells (DCs) are critical to the outcome of many viral infections. Questions still remain as to the relevance of artificially generated DCs in models of in vivo immune responses. We compared different DC generation pathways, in terms of phenotypic expression, cytokine production, apoptosis, and T cell proliferation, following viral infection. Direct viral infection of monocytes or monocytes cultured with supernatants from virally infected lung epithelial cells (A549 DCs) induce distinct DC subsets compared with viral infection of artificially generated IL-4 DCs and IFN-DCs. These virally infected DC subsets stimulated different cytokine secretion profiles and displayed contrasting sensitivities to viral-induced apoptosis. It is most interesting that we observed marked differences in the proliferation of purified CD3+ T cells from the virally infected DC subsets. In conclusion, artificially generated DCs skew immune responses to viral infections, and direct viral infection of monocytes and DCs, generated from monocytes cultured with supernatants from infected epithelial cells, appears to be a more relevant pathway of producing DCs, which mimic those generated in vivo.     

Intestinal immune homeostasis is regulated by the crosstalk between epithelial cells and dendritic cells

The control of damaging inflammation by the mucosal immune system in response to commensal and harmful ingested bacteria is unknown. Here we show epithelial cells conditioned mucosal dendritic cells through the constitutive release of thymic stromal lymphopoietin and other mediators, resulting in the induction of 'noninflammatory' dendritic cells. Epithelial cell-conditioned dendritic cells released interleukins 10 and 6 but not interleukin 12, and they promoted the polarization of T cells toward a 'classical' noninflammatory T helper type 2 response, even after exposure to a T helper type 1-inducing pathogen. This control of immune responses seemed to be lost in patients with Crohn disease. Thus, the intimate interplay between intestinal epithelial cells and dendritic cells may help to maintain gut immune homeostasis.     

The regulatory role of dendritic cells in the immune response

Dendritic cells (DCs) are key regulators of immune reactions. They control early innate responses, regulate long-lasting adaptive immunity and contribute to the maintenance of self-tolerance. DCs continuously monitor the environment through a multifaceted innate antigen receptor repertoire and, in response to perturbations, start a complex genetic reprogramming that leads to a complete activation of innate and, then, adaptive immune responses. This review discusses how DCs become efficient activators of NK and, subsequently, T cells following a microbial encounter.     

Reciprocal stimulation of gammadelta T cells and dendritic cells during the anti-mycobacterial immune response

Gammadelta T cells and dendritic cells (DC) are two distinct cell types of innate immunity that participate in early phases of immune response against Mycobacterium tuberculosis infection. Here we show that a close functional relationship exists between these cell populations. Using an in vitro coculture system, Vgamma1 T cells from Tcrb(-/- )mice were found to be activated by DC infected in vitro with BCG, as indicated by the elevated CD69 expression, IFN-gamma secretion and cytotoxic activity. This activation process was due to a non-cognate mechanism since it required neither cell to cell contact nor interaction between the TCR and a specific antigen, but was mediated by DC-derived IL-12. Reciprocally, Vgamma1 T cells provided a key cytokine, IFN-gamma, which increased IL-12 production by BCG-infected DC. Moreover, exposure of BCG-infected DC to Vgamma1 T cells conditioned the former to prime a significantly stronger anti-mycobacterial CD8 T cell response. Consequently, stimulation of gammadelta T cells and their non-cognate interaction with DC could be applied as an immune adjuvant strategy to optimize vaccine-induced CD8 T cell immunity.