夏氏疟原虫感染过程中调节性B细胞的表达变化

调节性B细胞(regulatory B cells,Bregs)是近年来发现的通过分泌IL-10发挥免疫调节作用的B细胞,其在疟疾免疫应答中的作用尚不清楚。利用血液阶段夏氏疟原虫(Plasmodium chabaudi AS,P.c AS)感染的BALB/c小鼠,观察了感染过程中Bregs数量变化及其表面分子表达情况。结果显示,BALB/c小鼠感染P.c AS后红细胞感染率逐渐升高,于感染后第9天达到30%,多数小鼠死亡。脾组织细胞因子IL-10 mRNA水平在感染后显著升高,感染后第5天达到高峰,感染后第8天仍为正常小鼠的10倍左右。CD4+细胞中IL-10+细胞百分比和绝对数量在感染后第5天达到峰值,于感染后第8天回落至正常水平;而CD19+细胞中IL-10+细胞(Bregs)百分比在感染后持续上升,在感染后第8天达到CD19+细胞的5%左右;感染后第5天,脾中CD4+IL-10+细胞绝对数量高于CD19+IL-10+细胞,至感染后第8天,CD19+IL-10+细胞绝对数量显著高于CD4+IL-10+细胞(P﹤0.01),约90%Bregs为CD5-细胞。结果提示,P.c AS感染过程中Bregs显著活化,是感染1周后IL-10的主要产生细胞。     

CD4+CD25+调节性T细胞、IL-2与免疫耐受

近年来,越来越多的研究表明CD4+CD25+调节性T细胞在免疫耐受的过程中起着非常重要的作用。IL-2作为一种T细胞生长因子调控着调节性T细胞诱导免疫耐受的过程。IL-2维持着中枢及外周的调节性T细胞的活性,但是对胸腺调节性T细胞的发育是非必要的。同时,IL-2信号影响着调节性T细胞的功能并维持着其的竞争适应性。因此,CD4+CD25+调节性T细胞通过与IL-2之间形成的免疫网络调控着免疫耐受的过程,从而影响着机体的免疫平衡。     

活化的肝星状细胞RBP-J可诱导性基因敲除小鼠的构建及应用

目的:利用Cre-loxp可诱导系统构建活化的肝星状细胞RBP-J可诱导性基因敲除小鼠模型,以实现肝纤维化过程中活化的肝星状细胞Notch信号通路的特异性阻断。方法:将Sm22αCre ERT2和RBP-Jflox/flox转基因小鼠杂交,得到F1小鼠,将繁殖的F1小鼠继续进行交配,得到F2小鼠,通过PCR鉴定出基因型为Sm22αCre ERT2,RBP-Jflox/flox的小鼠。通过腹腔注射四氯化碳建立肝纤维化模型,检测四氯化碳注射不同时间段后肝脏纤维化进展情况和肝星状细胞活化过程中Sm22α的表达情况。注射他莫昔芬诱导活化肝星状细胞中RBP-J基因的特异性敲除。分选肝星状细胞,q-PCR和Western Blot检测活化肝星状细胞中Notch下游靶基因Hes1、Hey1表达情况以验证敲除效果。结果:通过连续交配我们获得了Sm22αCre ERT2,RBP-Jflox/flox小鼠。四氯化碳腹腔注射4周即可诱导肝脏发生较为明显的纤维化,同时肝星状细胞活化并逐渐高表达Sm22α。给予他莫昔芬诱导Cre重组酶发挥作用后,敲除了活化的肝星状细胞中的RBP-J基因,其下游基因Hes1、Hey1表达降低70%以上,阻断了Notch信号通路。结论:我们成功构建了RBP-J可诱导性条件性基因敲除小鼠模型,实现了小鼠肝纤维化过程中活化肝星状细胞Notch信号通路的阻断,为深入研究Notch信号通路在肝纤维化中的作用和机制奠定了坚实的基础。     

MiR-150缺失增强小鼠NKT细胞IFN-γ产生并抑制黑色素瘤细胞的肺转移

CD1d限制性NKT细胞(自然杀伤T细胞)是一群具有免疫调节功能的T细胞亚群,在调控多种免疫应答中发挥重要作用．MicroRNAs介导的RNA干扰已被证明是调控NKT细胞发育和功能的关键分子机制,然而特异microRNA在NKT细胞发育和功能中的作用目前仍不清楚．在本研究中,我们采用miR-150基因敲除小鼠以及流式细胞术、ELISA等方法,观察miR-150对小鼠NKT细胞发育和功能的影响．结果表明：miR-150基因缺失致小鼠胸腺NKT细胞数量减少,但不影响外周NKT细胞的数量;活化后miR-150敲除小鼠NKT细胞与野生型小鼠NKT细胞相比,IFN-γ产生增加．进一步采用小鼠黑色素瘤模型观察miR-150对肿瘤细胞转移的影响,发现miR-150敲除显著增强半乳糖神经鞘氨醇(α-Galcer)对小鼠黑色素瘤细胞肺转移的抑制效果．上述结果为特异microRNA调控NKT细胞发育和功能的研究提供了新的线索．     

调节性B细胞的发现和研究进展

B细胞主要通过呈递抗原和产生抗体发挥免疫调节作用.新近研究表明,一种全新的B细胞亚群--调节性B细胞(regulatory B cell,Bregs),可通过产生白细胞介素10(IL-10)或转化生长因子β1(TGF-β1)等抑制性细胞因子介导免疫耐受,抑制过度炎症反应.Bregs在一些慢性炎性疾病包括肠炎、类风湿性关节炎、实验性自身免疫脑脊髓炎、多发性硬化症、感染和肿瘤等发生、发展和转归过程起重要调节作用.Bregs的发现和作用机制的阐明,将为全面、深入了解免疫耐受的机制,寻找和开发更合理治疗慢性炎性疾病的策略提供理论依据.本文综述了Bregs的发现、生物学特征、发育调节及其参与炎性疾病发病的作用和机制.     

影响CD4+CD25+T细胞分化发育的细胞分子机制

免疫耐受的精髓即机体对外界病原体抗原产生免疫应答的同时对自身抗原不应答.近两年对CD4 CD25 调节性T细胞(CD4 CD25 regulatory T cell, Treg)所发挥的免疫耐受功能的研究取得了令人瞩目的长足进展,对此群细胞所具有的维持外周免疫耐受的独特地位已无可争议.但调节性T细胞的多种生物学特征特别是Treg细胞分化发育的分子机制与信号需求并不清楚,因此探索有关Treg的发生发育及其影响机制已成为近两年研究Treg细胞的热点.综述最近的相关研究数据,了解胸腺以及外周影响Treg细胞分化发育和功能产生的多种细胞分子机制,有助于进一步研究此群细胞的功能及其在抑制自身免疫性疾病、诱导移植耐受等方面的应用.     

Notch 信号通路与淋巴细胞发育

Notch 信号通路为一广泛应用且高度保守的信号转导途径,决定多能祖细胞的分化方向,其中在共同淋巴祖细胞向 T 淋巴细胞或 B 淋巴细胞分化选择中具有决定性作用 . Notch 信号通路参与淋巴细胞的发育过程,促进 Tαβ细胞的形成、诱导处女型 T 细胞变为调节型 T 细胞、阻止 CD4+T 细胞向 Th1 类型分化,以及增加外周免疫器官边缘区 B 细胞的数量 . 在分析 Notch 蛋白结构的基础上,综合最新进展,系统阐明了 Notch 信号通路的组成、作用机制、参与的淋巴细胞发育过程以及所起的作用 .     

天然型调节性T细胞发育分化的研究进展

CD4 CD25 调节性T细胞(Treg)对维持自身免疫耐受及调控免疫应答水平发挥非常重要的作用．Treg的缺失或紊乱导致如多发性硬化症、1型糖尿病等自身免疫性疾病的发生．研究发现,Treg在肿瘤免疫、感染免疫和移植免疫耐受中也发挥关键作用．根据来源不同,可将Treg分为胸腺来源的天然型Treg(natural Treg)和外周诱导型Treg(induced Treg)两群．天然型Treg(nTreg)是由胸腺发育分化成熟的,nTreg存在于胸腺CD4单阳性细胞中,表达CD4、CD25及叉头转录因子Foxp3,主要通过细胞与细胞之间直接接触发挥免疫抑制功能．研究表明,nTreg在胸腺中发育分化受到十分复杂的细胞、分子网络调控．胸腺微环境、T细胞受体、共刺激分子、IL-2等信号都可影响nTreg的发育分化．本文将主要对胸腺nTreg的发育分化过程及分子调控等方面进行综述．     

调节性B细胞及其在类风湿关节炎中的研究进展

调节性B细胞(regulatory B cells, Bregs)是一类具有免疫抑制功能的B细胞亚群,可通过表达分化抗原1d(cluster of differentiation 1d, CD1d)、凋亡相关因子配体(factor related apoptosis ligand, FasL)、程序性死亡配体-1(programmed death ligand-1, PD-L1)等膜结合因子,分泌白细胞介素-10(interleukin-10, IL-10)、IL-35、转化生长因子-β(transforming growth factor-β, TGF-β)、颗粒酶B和腺苷等多种机制发挥其免疫抑制功能。近年研究发现,Bregs在类风湿关节炎(rheumatoid arthritis, RA)发病机制中起到重要作用,且有可能成为治疗RA等自身免疫性疾病的新靶点。现就Bregs及其在RA中的研究进展作一概述。     

Foxp3~+ Treg诱导免疫耐受与器官移植

调节性T细胞(regulatory T cell,Treg)是指具有免疫调节功能的T细胞。自然发育的CD4+CD25+Treg,特异的表达叉头状家族转录因子Foxp3,也称Foxp3+Treg,在维持免疫耐受和免疫稳态方面发挥重要的功能。根据来源可将Foxp3+Treg分为天然Treg(natural Treg,n Treg)和可诱导Treg(induced Treg,i Treg)。本综述总结了Foxp3+Treg及效应性T细胞的发育及其调控机制相关的信号通路,探讨了Foxp3+Treg诱导免疫耐受的作用机制。一些免疫抑制剂如雷帕霉素(rapamycin,RAPA)和最近应用的芬戈莫德(fingolimod,FTY720)等在器官移植后可用来诱导免疫耐受,研究发现这些药物不仅对效应性T细胞的分化、发育有抑制作用,同时对Foxp3+Treg的发育也有重要的影响。     

Induction of IL-10-producing regulatory B cells following Toxoplasma gondii infection is important to the cyst formation

Toxoplasma gondii is a protozoan parasite that infects humans and animals via congenital or postnatal routes. During parasite infection, IL-10-producing Bregs are stimulated as part of the parasite-induced host immune responses that favor infection. In this study, we investigated whether T. gondii infection induces immune regulatory cells including IL-10-producing CD1d^highCD5⁺ regulatory B cells (Bregs) and whether Breg induction is critical for the development of chronic infection of T. gondii. Furthermore, B cell-deficient (μMT) mice revealed that the IL-10-producing B cells might be associated with the development of chronic T. gondii infection. To better understand the mechanism underlying the accumulation of IL-10-producing B cells upon T. gondii infection, we determined the effect of products released by T. gondii on the induction and differentiation of IL-10-producing B cells during the acute stage of infection using transgenic green fluorescent protein (GFP)-expressing T. gondii strain. We demonstrated that products secreted at the stage of cell lysis by fully replicated tachyzoites induced the differentiation of naive B cells to IL-10-producing Bregs. Our results indicated that the downregulation of the immune response via Bregs during T. gondii infection is related to cyst formation in the host brain and to the establishment of chronic infection.     

Mice lacking endogenous IL-10-producing regulatory B cells develop exacerbated disease and present with an increased frequency of Th1/Th17 but a decrease in regulatory T cells

IL-10-producing B cells, also known as regulatory B cells (Bregs), play a key role in controlling autoimmunity. In this study, we report that chimeric mice specifically lacking IL-10-producing B cells (IL-10(-/-)B cell) developed an exacerbated arthritis compared with chimeric wild-type (WT) B cell mice. A significant decrease in the absolute numbers of Foxp3 regulatory T cells (Tregs), in their expression level of Foxp3, and a marked increase in inflammatory Th1 and Th17 cells were detected in IL-10(-/-) B cell mice compared with WT B cell mice. Reconstitution of arthritic B cell deficient (μMT) mice with different B cell subsets revealed that the ability to modulate Treg frequencies in vivo is exclusively restricted to transitional 2 marginal zone precursor Bregs. Moreover, transfer of WT transitional 2 marginal zone precursor Bregs to arthritic IL-10(-/-) mice increased Foxp3(+) Tregs and reduced Th1 and Th17 cell frequencies to levels measured in arthritic WT mice and inhibited inflammation. In vitro, IL-10(+/+) B cells established longer contact times with arthritogenic CD4(+)CD25(-) T cells compared with IL-10(-/-) B cells in response to Ag stimulation, and using the same culture conditions, we observed upregulation of Foxp3 on CD4(+) T cells. Thus, IL-10-producing B cells restrain inflammation by promoting differentiation of immunoregulatory over proinflammatory T cells.     

IL-10 producing regulatory B cells in mice and humans: state of the art

IL-10-producing regulatory B cells have been undoubtedly identified in mice and shown to downregulate inflammation, making them potentially important for maintenance of tolerance. Several recent works have also identified IL-10 producing regulatory B cells in humans and have begun to unravel their phenotype and mode of suppression. Cell surface phenotype of human Bregs includes CD38, CD27, CD24 and CD5. Mechanisms of suppression may imply inhibition of CD4+ T proliferation, inhibition of Th1 differentiation, induction of regulatory T cells and suppression of monocytes activation. These recent findings imply that manipulating IL-10 production by human B cells could be a useful therapeutic strategy for modulating immune responses in humans.     

Interleukin 35 Regulatory B Cells

B lymphocytes play a central role in host immunity. They orchestrate humoral immune responses that modulate activities of other immune cells and produce neutralizing antibodies that confer lasting immunity to infectious diseases including smallpox, measles and poliomyelitis. In addition to these traditional functions is the recent recognition that B cells also play critical role in maintaining peripheral tolerance and suppressing the development or severity of autoimmune diseases. Their immune suppressive function is attributed to relatively rare populations of regulatory B cells (Bregs) that produce anti-inflammatory cytokines including interleukin 10 (IL-10), IL-35 and transforming growth factor-β. The IL-35-producing B cell (i35-Breg) is the newest Breg subset described. i35-Bregs suppress central nervous system autoimmune diseases by inducing infectious tolerance whereby conventional B cells acquire regulatory functions that suppress pathogenic Th17 responses. In this review, we discuss immunobiology of i35-Breg cell, i35-Breg therapies for autoimmune diseases and potential therapeutic strategies for depleting i35-Bregs that suppress immune responses against pathogens and tumor cells.     

B7/CD28-dependent CD4+CD25+ regulatory T cells are essential components of the memory-protective immunity to Candida albicans

Protective immunity to the fungus Candida albicans is mediated by Ag-specific Th1 cells. Paradoxically, some Th2 cytokines are required for the maintenance of Th1-mediated immune resistance to the fungus. Therefore, in addition to the Th1/Th2 balance, other mechanisms seem to be involved in the regulation of Th1 immunity to the fungus. Here we show that CD4(+)CD25(+) T cells, negatively regulating antifungal Th1 reactivity, are generated in mice with candidiasis. CD4(+)CD25(+) T cells were not generated in B7-2- or CD28-deficient mice or in condition of IL-10 signaling deficiency. Accordingly, although capable of efficiently restricting the fungal growth, these mice experienced inflammatory pathology and were incapable of resistance to reinfection. CD4(+)CD25(+) T cells poorly proliferated in vitro; were highly enriched for cells producing IL-4, IL-10, and TGF-beta; and required IL-10-producing, Candida hypha-activated dendritic cells for generation. Adoptive transfer of CD4(+)CD25(+) T cells or IL-10-producing dendritic cells restored resistance to reinfection and decreased inflammation in B7-2-deficient mice. These results show that oral tolerance induced by Candida hyphae is required for the occurrence of long-lasting protective immunity after yeast priming. The implication is that preventing reactivation rather than favoring sterilizing immunity to ubiquitous fungal pathogens may represent the ultimate expectation of vaccine-based strategies.     

口服卡介菌诱导免疫耐受的CD4^＋CD25^＋调节性T细胞机制研究

目的：研究口服卡介菌诱导免疫耐受对CD4^＋CD25^＋调节性T细胞的影响。方法：采用口服MPB制备EAE大鼠模型,随机分为BCG组（0.5mg/kg）和EAE模型组（PBS）,每组各15只,连续经口灌服给药14d,同时选取15只健康大鼠作为对照组。分别于免疫后15d、27d流式细胞术检测外周血、胸腺及脾脏中CD4^＋CD25^＋T淋巴细胞百分率,ELISA检测血清IL-6、TGF-β、IgE、IgG含量。结果：与EAE模型组相比,免疫后BCG组大鼠外周血、胸腺及脾脏中CD4^＋CD25^＋T淋巴细胞百分率增加,血清IL-6、TGF-β含量上升,血清IgE、IgG抗体水平下降。结论：口服BCG通过上调淋巴器官中CD4^＋CD25^＋T淋巴细胞比例,抑制效应性T细胞活性,发挥免疫耐受作用。