浅论小鼠脾脏来源树突状细胞的体外扩增培养.docx

1、浅论小鼠脾脏来源树突状细胞的体外扩增培养 【摘要】 目的：对体外诱导小鼠脾脏单个核细胞分化成的树突状细胞(DC)的生物学表型及功能进行检测，并与骨髓来源的DC进行比较。方法：分离小鼠脾脏单个核细胞，在体外培养的条件下通过添加25 ng·ml-1的粒单核细胞集落刺激因子和25 ng·ml-1的白细胞介素4(IL4)将其诱导为DC，分别从细胞形态、表型以及功能3个方面对其进行检测，并与骨髓来源的DC进行比较。结果：小鼠脾脏来源的DC经磷酸脂多糖(LPS)刺激成熟后其表面显示出明显的树枝状突起，高表达CD11c、CD86及MHCⅡ类分子，并具有极强的刺激同种异基因淋巴细胞增殖的能力，其特征

2、与骨髓来源的DC相差无几。结论：小鼠脾脏单个核细胞能够被诱导为具有正常形态、表型、功能的DC，为DC的功能研究以及进一步制备相应的肿瘤疫苗提供又一可靠来源。 【关键词】 脾脏; 骨髓; 树突状细胞; 诱导; 小鼠 　Dendritic cells(DC) are the most potent antigen presenting cells that are responsible for priming native T cells in the immune response. Immunotherapy of DC/tumor vaccine has become an impor

3、tant therapeutic strategy against tumors[12]. However, the basic and clinical applications of DCs have been limited by the low yield and purity of DCs generated by traditional bone marrow derivation. In this study, we induced mouse spleen mononuclear cells into dendritic cells in vitro, and then co

4、mpared the biological characteristics of them with those of bone marrow mononuclear cells derived DCs. 　　1 Materials and methods 　　Materials 　　Main reagents: recombinant mouse granulocytemacrophage colonystimulating factor(GMCSF), recombinant mouse interleukin4(IL4), recombinant mouse leukem

5、ia inhibitory factor(LIF,Peprotech), lipopolysaccharide(LPS,Sigma); mitomycin C(MMC) and methabenzthiazuron(MTT,Duchfo). DCs culture medium: high glucose DMEM plus 15% fetal calf serum plus 25 mg·L-1 rmGMCSF and rmIL4. Mice: six to eight weeks old female BALB/c and 129 mice were purchased from Ani

6、mal Center of Guiyang Medical College. 　　Methods 　　Induction of DC from mouse spleen Cells were flushed out of spleen of 129　cells at the interface were collected by centrifugation over a lympholyte gradient. They were washed and then cultured in 6well plate for 2 h with the density of 5×104　susp

7、ended cells were removed and the adherent cells were cultured with DC culture medium. LPS was added on day 7 and the suspended cells were harvested 24 h later, while at the same time mouse bone mononuclear cells were induced into DCs. 　　Morphology observation Cells were observed under microscope da

8、ily and suspended cells were identified by electron microscopy. 　　Cell surface marker analysis Cells were collected and added into centrifuge tube. Mixed with FITCCD11c and MHCⅡPE, FITCCD86 and MHC IIPE, respectively, the cells were kept at 4 ℃ for 30 min. After being washed twice by PBS,cells

9、were assayed by flow cytometry. 　　Mixed lymphocyte reactions(MLR) Collected spleen derived DC were added with 25 μg·ml-1 MMC as a stimulator for 45 min and washed twice. Nylon wool purified Tcel1s as responders were added in 96well round bottom plates at various ratios for 4　the same time, we set

10、 control group that didnt include stimulators. 4 h before harvesting, cells were pulsed with 20 μl MTT(5 mg·ml-1), then added with 100 μl DMSO and its absorbency was measured. The stimulation index was calculated according to the following formula: SI= absorbency of stimulation groupabsorbency of

11、contrast/the absorbency of contrast. 　　Statistical analysis 　　Data are expressed as ±s　results of the analysis was shown by t　value of　was considered statistically significant. 　　2 Results 　　Morphological characteristics of mouse spleen derived DCs 　　At the first 2-4 d, the mouse spleen mononuc

12、lear cells grew slowly and round in shape, the bulk was small, the population expanded rapidly with time and then the bulk became larger　spleen derived DCs already had irregular dendrites after being cultured for 5-7 d. After adding 1 μg·ml-1 of LPS for 24 h, the dramatic veils of cytoplasm and exte

13、nsive dendrites were more distinct(Fig 1), just as the mature BMDCs. Besides, 5-10 cell conglomerates could be seen(Fig 2). By electromicroscopy the dramatic veils of cytoplasm and extensive dendrites were seen more clearly(Fig 3). 　　Analysis of surface phenotype 　　DCs derived from mouse spleen

14、mononuclear cells were induced to mature through exposure to LPS and high expression of surface molecules MHCⅡand CD86 was associated with antigen　expression of peculiar surface molecule CD11c(Fig 4) in spleenDCs was just as that in BMDCs. 　　MLR 　　Following exposure to LPS,mouse spleen derived

15、DCs were induced and became mature, which demonstrated their capacity to stimulate potent primary T cell responses in mixed lymphocyte cultures(Tab 1).Tab 1 Stimulation index for primary T cell of twosource derived DCs(±s) 　　3 Discussion 　　DCs are unique among populations of antigen presenting ce

16、lls by the virtue of their capacity to direct the outcome of antigen recognition by naive T cells. DCs in the periphery capture and process antigens, express lymphocyte costimulatory molecules,migrate to lymphoid organs and secrete cytokines to initiate immune　studies have shown that DCs play cruci

17、al roles in controlling tumor growth, graft rejection and　present, we have already induced DCs from bone marrow, etc.[57], and will produce antitumor vaccine by gene transfection, tumorassociated antigen impaction and cell fusion[810]. The effects of research in experimental animal were exciting

18、 Furthermore, DC immunotherapy has been introduced in the clinic, and has been proved to be feasible, nontoxic and effective in some cancer patients, and particularly so when the DCs are completely mature and activated[11]. The results of the first clinical trial have been published, and unequivoc

19、ally demonstrated that only mature DCs are capable of inducing potent antiKLHspecific Tcell and Bcell response[12]. The life cycle of DC includes several stages characterized by distinct functions and mechanisms of regulation[13]. The DCs derived from different sources or at different life stage

20、s may have different biological characteristics[1418]. 　　In the present study, we induced DCs differentiated from mouse spleen mononuclear　results showed that it could be induced into DCs with normal surface phenotype in vitro by additional appropriate signals in the form of growth factors and　dra

21、matic veils of cytoplasm and extensive dendrites were seen in their surface when they were induced and matured by adding LPS,and they expressed the myeloid peculiar surface molecule CD11c, MHCⅡand CD86 which were associated with antigen presenting. Compared with BMDC, the surface morphological cha

22、racteristics of them were similar. They have already had a few irregular dendrites before maturity by plus LPS,and expressed lower levels of CD11c, MHCⅡ, CD86. Induced into mature by LPS, the characteristics were more evident. Mouse spleen mononuclear cell derived mature DCs demonstrates their capa

23、city to stimulate potent primary T cell responses in mixed lymphocyte reactions. There was no statistical difference compared with BMDC. From this research, we can conclude that mouse spleen derived DCs have analogical biological characteristics to those in BMDC which has been applied in basic and

24、 clinical research. Therefore it provides a reliable source for the research of DCs and the preparation of antitumor vaccine in the next step. 【参考文献】 　[1] FLEMING J N, HOSTIKKA S L, CHEN E Y, et al. Plasmacytoid dendritic cells and interferon levels are increased in lymphatic malformations[J]. O

25、tolaryngol Head Neck Surg,2008，139(5):671676. 　　ZOU G M, MARTINSON J, HU W Y, et al. The effect of LIGHT in inducing maturation of monocytederived dendritic cells from MDS patients[J]. Cancer Immunol Immunother,2004,53(8):681689. 　　CHAUVIN C, JOSIEN R. Dendritic cells as killers: mechanistic a

26、spects and potential roles[J]. Immunol,2008,181:1116. 　　BANCHEREAU J, STEINMAN R M. Dendritic cells and the control of immunity[J]. Nature,1998,392:245252. 　　DOMINQUEZSOTO A, CORBI A　dendritic cell lectins and their role in immune responses[J]. Curr Opin Investig Drugs,2007,8:910920. 　　BRUNO

27、L. Differentiation of dendritic cell subsets from mouse bone marrow[J]. Methods Mol Biol,2007,380:4757. 　　OGAWA F, IINUMA H, OKINAGA K. Dendritic cell vaccine therapy by immunization with fusion cells of interleukin2 genetransduced, spleenderived dendritic cells and tumour cells[J]. Scand J Imm

28、unol,2004,59:432439. 　　den BROK M H, NIERKENS S, FIGDOR C G, et al. Dendritic cells: tools and targets for antitumor vaccination[J]. Expert Rev Vaccines,2005,4:699710. 　　BANCHEREAU J,PALUCKA A　cells as therapeutic vaccines against cancer[J]. Nat Rev Immunol,2005,5:296306. 　　[10] GONG J, KOIDO

29、S, CALDERWOOD S K. Cell fusion: from hybridoma to dendritic cellbased vaccine[J]. Expert Rev Vaccines,2008,7:10551068. 　　[11] AARNTZEN E H, FIGDOR C G, ADEMA G J, et al. Dendritic cell vaccination and immune monitoring[J]. Cancer Immunol Immunother,2008,57:15591568. 　　[12] de VRIES I J, LESTERH

30、UIS W J, SCHARENBORG N M, et al. Maturation of dendritic cells is a prerequisite for inducing immune responses in advanced melanoma patients[J]. Clin Cancer Res,2003,9:50915100. 　　[13] CHOW A, TOOMRE D, GARRETT W, et al. Dendritic cell maturation triggers retrograde MHC class Ⅱ transport from lyso

31、somes to the plasma membrane 　　[J]. Nature,2002,418:988994. 　　[14] KATSNELSON A. Kicking off adaptive immunity: the discovery of dendritic cells[J]. J Exp Med,2006,203(7):1622. 　　[15] MENGES M, BAUMEISTER T, ROSSNER S, et al. IL4 supports the generation of a dendritic cell subset from murine bo

32、ne marrow with altered endocytosis capacity[J]. J Leukoc Biol,2005,77(4):535543. 　　[16] BASHYAM H. Ralph Steinman: dendritic cells bring home the Lasker[J]. J Exp Med,2007,204(10):22452248. 　　[17] TAN J K, ONEILL H C. Maturation requirements for dendritic cells in T cell stimulation leading to tolerance versus immunity[J]. J Leukoc Biol,2005,78(2):319324. 　　[18] 鲍文,陈宝安,丁家华.抗原递呈细胞在异基因造血干细胞移植中的研究进展[J].东南大学学报:医学版,2006,25(2):122125.