血紅素結合蛋白在A型鏈球菌的致病機轉中所扮演的角色

Yao-Cheng Yang; 楊曜誠

請用此 Handle URI 來引用此文件： http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/49733

完整後設資料紀錄

DC 欄位	值	語言
dc.contributor.advisor	張永祺(Yung-Chi Chang)
dc.contributor.author	Yao-Cheng Yang	en
dc.contributor.author	楊曜誠	zh_TW
dc.date.accessioned	2021-06-15T11:44:52Z	-
dc.date.available	2021-08-26
dc.date.copyright	2016-08-26
dc.date.issued	2016
dc.date.submitted	2016-08-12
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Microbial manipulation of receptor crosstalk in innate immunity. Nature reviews Immunology 11, 187-200. Henningham, A., Yamaguchi, M., Aziz, R.K., Kuipers, K., Buffalo, C.Z., Dahesh, S., Choudhury, B., Van Vleet, J., Yamaguchi, Y., Seymour, L.M., et al. (2014). Mutual exclusivity of hyaluronan and hyaluronidase in invasive group A Streptococcus. The Journal of biological chemistry 289, 32303-32315. Hermans, J., and McDonagh, J. (1982). Fibrin: structure and interactions. Seminars in thrombosis and hemostasis 8, 11-24. Huntoon, K.M., Wang, Y., Eppolito, C.A., Barbour, K.W., Berger, F.G., Shrikant, P.A., and Baumann, H. (2008). The acute phase protein haptoglobin regulates host immunity. Journal of leukocyte biology 84, 170-181. Kasvosve, I., Speeckaert, M.M., Speeckaert, R., Masukume, G., and Delanghe, J.R. (2010). Haptoglobin polymorphism and infection. Advances in clinical chemistry 50, 23-46. Kohler, W., and Prokop, O. (1978). Relationship between haptoglobin and Streptococcus pyogenes T4 antigens. Nature 271, 373. Lancefield, R.C. (1933). A Serological Differentiation of Human and Other Groups of Hemolytic Streptococci. The Journal of experimental medicine 57, 571-595. Lang, T., Johanning, K., Metzler, H., Piepenbrock, S., Solomon, C., Rahe-Meyer, N., and Tanaka, K.A. (2009). The effects of fibrinogen levels on thromboelastometric variables in the presence of thrombocytopenia. Anesthesia and analgesia 108, 751-758. Langlois, M.R., and Delanghe, J.R. (1996). Biological and clinical significance of haptoglobin polymorphism in humans. Clinical chemistry 42, 1589-1600. Li, Z., Sakota, V., Jackson, D., Franklin, A.R., Beall, B., and Active Bacterial Core Surveillance/Emerging Infections Program, N. (2003). Array of M protein gene subtypes in 1064 recent invasive group A streptococcus isolates recovered from the active bacterial core surveillance. The Journal of infectious diseases 188, 1587-1592. Lorand, L., and Konishi, K. (1964). Activation of the Fibrin Stabilizing Factor of Plasma by Thrombin. Archives of biochemistry and biophysics 105, 58-67. Mantovani, A., Garlanda, C., Doni, A., and Bottazzi, B. (2008). Pentraxins in innate immunity: from C-reactive protein to the long pentraxin PTX3. Journal of clinical immunology 28, 1-13. McMillan, S.J., Sharma, R.S., McKenzie, E.J., Richards, H.E., Zhang, J., Prescott, A., and Crocker, P.R. (2013). Siglec-E is a negative regulator of acute pulmonary neutrophil inflammation and suppresses CD11b beta2-integrin-dependent signaling. Blood 121, 2084-2094. Muszbek, L., Bagoly, Z., Bereczky, Z., and Katona, E. (2008). The involvement of blood coagulation factor XIII in fibrinolysis and thrombosis. Cardiovascular & hematological agents in medicinal chemistry 6, 190-205. Pepys, M.B., and Hirschfield, G.M. (2003). C-reactive protein: a critical update. The Journal of clinical investigation 111, 1805-1812. Secundino, I., Lizcano, A., Roupe, K.M., Wang, X., Cole, J.N., Olson, J., Ali, S.R., Dahesh, S., Amayreh, L.K., Henningham, A., et al. (2016). Host and pathogen hyaluronan signal through human siglec-9 to suppress neutrophil activation. Journal of molecular medicine 94, 219-233. Smeesters, P.R., McMillan, D.J., and Sriprakash, K.S. (2010). The streptococcal M protein: a highly versatile molecule. Trends in microbiology 18, 275-282. Steer, A.C., Batzloff, M.R., Mulholland, K., and Carapetis, J.R. (2009a). Group A streptococcal vaccines: facts versus fantasy. Current opinion in infectious diseases 22, 544-552. Steer, A.C., Law, I., Matatolu, L., Beall, B.W., and Carapetis, J.R. (2009b). Global emm type distribution of group A streptococci: systematic review and implications for vaccine development. The Lancet Infectious diseases 9, 611-616. Taranta, A., and Moody, M.D. (1971). Diagnosis of streptococcal pharyngitis and rheumatic fever. 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Invasive group A streptococcal disease in children in Queensland. Epidemiology and infection 139, 623-628.
dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/49733	-
dc.description.abstract	細菌藉助表面的一些特殊成分和結構，吸附於人體皮膚黏膜的表面，以不同的方式引起疾病。A型鏈球菌 (group A Streptococcus, GAS)，是人類中常見的傳染性致病菌，可引起各種疾病，如急性咽炎、蜂窩性組織炎、猩紅熱、壞死性筋膜炎，也可能導致肺部感染或是全身性感染等等。大部分A型鏈球菌會表現hyaluronic acid莢膜，藉此逃避宿主的免疫攻擊，先前研究指出，A型鏈球菌serotype M4 (GAS M4) 沒有hyaluronic acid莢膜的存在，卻依然會造成許多的侵入性的疾病感染，因此我們想研究其中的作用機制和病原菌與宿主間的交互作用，以了解GAS M4造成侵入性疾病的原因。在宿主發炎及感染時，急性期蛋白會被大量合成、釋放，並且增加蛋白表面的醣基化程度，其中一個急性期蛋白—血紅素結合蛋白(haptoglobin)之前已被報導過會抑制細胞激素的表現以及發炎反應。先前亦有研究指出，GAS M4可能與血紅素結合蛋白有特定的鍵結；另一方面，血紅素結合蛋白會鍵結表現在免疫細胞上的Immunoglobulin-like lectins (Siglecs)。Siglecs中Siglec-9與血紅素結合蛋白的親和力最明顯，並且具有Immunoreceptor tyrosine-based inhibitory motif (ITIM)，主要表現在中性粒細胞以及巨噬細胞表面。因此，我們假設GAS M4可能藉由結合血紅素結合蛋白，經免疫細胞表面具有ITIM的Siglec-9受體傳遞訊號，進而影響細胞的的先天免疫反應。為了研究這個假說，實驗室建構一株無法與血紅素結合蛋白鍵結的 GAS M4基因剔除突變株M4ΔSpy0116以及建構表現Siglec-9受體的細胞株，藉此探討GAS M4藉由血紅素結合蛋白與Siglec-9受體鍵結來抑制細胞的免疫反應的可能性。目前實驗結果顯示，血紅素結合蛋白可以幫助GAS M4抑制細胞的殺菌能力以及降低細胞激素的表現，並且增加小鼠體內GAS M4細菌的存活率，導致小鼠死亡率上升。儘管在觀察表現Siglec-9受體的細胞株後，可以發現明顯的細菌存活數增加以及細胞激素表現下降，但是在沒有表現Siglec-9受體的細胞中還是可以看到一些差異。目前還無法確定Siglec-9受體的重要程度，所以未來將進一步探討GAS M4、血紅素結合蛋白與Siglec-9受體之間的關聯性，或是尋找其他受體如Mac-1的可能性。	zh_TW
dc.description.abstract	Bacteria can adhere to the mucous lining on top of the surface of human skin by its own specialized surface components and structures to cause diseases in different levels. Group A Streptococcus (GAS) is a common human pathogen, and infection of GAS can either result in relatively mild diseases, such as acute pharyngitis, cellulitis, scarlet fever or in very severe, life-threatening diseases, including pneumonia, bacteremia, necrotizing fasciitis and streptococcal toxic shock syndrome. Most GAS isolates have a hyaluronic acid capsule and use it to evade the host immune response. Previous reports have demonstrated that GAS serotype M4 (GAS M4) is lacking this important hyaluronic acid capsule, but still causes many invasive infections, therefore we would like to further understand how GAS M4 interacts with host to achieve a successful infection and underlying mechanisms. During infection and inflammation, many acute-phase proteins (APPs) are massively synthesized, accompanying with increased sialylation and haptoglobin one of the APPs has been shown to have immune-suppressive effects on various in vivo and in vitro models. Previous reports have shown haptoglobin can bind to GAS M4, and we further found that haptoglobin can interact with multiple sialic acid-binding immunoglobulin-like lectins (Siglecs) expressed on various immune cells. Among the examined Siglecs, Siglec-9, an immunereceptor tyrosine-based inhibitory motif (ITIM) containing Siglec mainly expressed on neutrophils and macrophages, exhibits most robust interaction with haptoglobin. We are curious to examine whether GAS M4 can impair host innate immune responses via targeting the inhibitory ITIM-containing Siglecs-9 through haptoglobin. To address this hypothesis, we generated a GAS M4 isogenic strain lacking the haptoglobin binding ability (M4ΔSpy0116) as well as the Siglec-9 overexpressing cells to investigate the impacts of haptoglobin on the GAS M4 pathogenicity. Based on our preliminary data, GAS M4 can inhibit the bactericidal activity and cytokine release of innate immune cells via acquiring haptoglobin on its surface. The critical role of Spy0116 on the GAS M4 pathogenicity has also been demonstrated on the in vivo mice intraperitoneal infection model . The enhanced bacteria survival and decreased inflammatory cytokine expression can be observed in the presence or absence of Siglec-9, albeit it is more pronounced in the Siglec-9 expressing cells. It suggests that Siglec-9 may not be the only haptoglobin target on the innate immune cells and the role of Sigelc-9 needs to be further addressed.	en
dc.description.provenance	Made available in DSpace on 2021-06-15T11:44:52Z (GMT). No. of bitstreams: 1 ntu-105-R03445123-1.pdf: 2129112 bytes, checksum: 25f7f3e36ebb2855348504dd242d4e93 (MD5) Previous issue date: 2016	en
dc.description.tableofcontents	口試委員審定書 i 致謝 ii 中文摘要 iii Abstract iv 壹、序論 - 1 - 一、A型鏈球菌 (Group A Streptococcus) - 1 - 二、急性期蛋白 (Acute phase protein, APP) - 3 - 三、Sialic acid-binding immunoglobulin-like lectins (Siglecs) 受體 - 4 - 四、研究動機 - 5 - 貳、材料與研究方法 - 6 - 一、實驗菌種、細胞與質體 - 6 - 二、培養液與培養基 - 7 - 三、抗生素 - 7 - 四、中和抗體及染色抗體 - 8 - 五、設計引子 - 8 - 六、聚合酶連鎖反應 - 10 - 七、質體DNA萃取 - 10 - 八、Genomic DNA萃取 - 10 - 九、限制酶反應 - 10 - 十、DNA洋菜膠電泳分析 - 11 - 十一、電泳凝膠DNA回收 - 11 - 十二、接合反應 - 11 - 十三、DH5α勝任細胞與轉形作用 - 11 - 十四、電穿孔勝任細胞置備及電穿孔作用 - 11 - 十五、同源置換 - 12 - 十六、測試生長速率 - 12 - 十七、預先結合haptoglobin與GAS - 13 - 十八、GAS M4和haptoglobin與Siglec受體之間的親和力 - 13 - 十九、細胞轉染及病毒置備 - 13 - 二十、細胞基因導入 - 14 - 二十一、流式細胞儀分析 - 14 - 二十二、THP-1細胞殺菌能力試驗 - 15 - 二十三、RAW細胞殺菌能力試驗 - 15 - 二十四、萃取受細菌感染的細胞RNA - 16 - 二十五、RNA反轉錄 - 16 - 二十六、RNA表現量測定 - 16 - 二十七、萃取受細菌感染的細胞細胞激素 - 17 - 二十八、人類全血殺菌試驗 - 17 - 二十九、血液分離之中性粒細胞殺菌試驗 - 18 - 三十、動物實驗—死亡率 - 18 - 三十一、動物實驗—小鼠體內菌數及細胞激素表現 - 18 - 參、研究結果 - 19 - 一、GAS M4基因剔除株建立 - 19 - 二、基因剔除菌株驗證 - 19 - 三、對基因剔除株進行生長曲線測試 - 19 - 四、人類全血殺菌能力試驗 - 20 - 五、中性粒細胞殺菌試驗 - 20 - 六、動物實驗 - 21 - 七、探討細胞中對於haptoglobin抑制發炎反應的重要受體 - 21 - 八、Siglec-9細胞株建立 - 22 - 九、人類單核球THP-1細胞殺菌試驗 - 22 - 十、小鼠巨噬細胞RAW細胞殺菌試驗 - 22 - 十一、THP-1細胞及RAW細胞在GAS感染後細胞激素RNA表現量 - 23 - 十二、THP-1細胞激素分泌 - 23 - 十三、RAW細胞激素分泌 - 23 - 肆、討論 - 25 - 伍、未來研究方向 - 27 - 陸、圖目錄 - 28 - 附錄 - 44 - 參考文獻 - 45 -
dc.language.iso	zh-TW
dc.subject	A型鏈球菌	zh_TW
dc.subject	血紅素結合蛋白	zh_TW
dc.subject	Siglec受體	zh_TW
dc.subject	ITIM	zh_TW
dc.subject	Streptococcus pyogenes	en
dc.subject	Siglecs	en
dc.subject	ITIM	en
dc.subject	haptoglobin	en
dc.title	血紅素結合蛋白在A型鏈球菌的致病機轉中所扮演的角色	zh_TW
dc.title	Role of haptoglobin in M4 Group A Streptococcus pathogenesis	en
dc.type	Thesis
dc.date.schoolyear	104-2
dc.description.degree	碩士
dc.contributor.oralexamcommittee	邱浩傑,顧家綺(Chia-Chi Ku)
dc.subject.keyword	A型鏈球菌,血紅素結合蛋白,ITIM,Siglec受體,	zh_TW
dc.subject.keyword	Streptococcus pyogenes,haptoglobin,ITIM,Siglecs,	en
dc.relation.page	48
dc.identifier.doi	10.6342/NTU201602423
dc.rights.note	有償授權
dc.date.accepted	2016-08-15
dc.contributor.author-college	醫學院	zh_TW
dc.contributor.author-dept	微生物學研究所	zh_TW
顯示於系所單位：	微生物學科所

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