研究以酵母聚醣作為佐劑促進腸病毒A71型與D68型之鼻黏膜疫苗免疫反應

秦僑莉; Chiao-Li Chin

請用此 Handle URI 來引用此文件： http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/99346

完整後設資料紀錄

DC 欄位	值	語言
dc.contributor.advisor	江伯倫	zh_TW
dc.contributor.advisor	Bor-Luen Chiang	en
dc.contributor.author	秦僑莉	zh_TW
dc.contributor.author	Chiao-Li Chin	en
dc.date.accessioned	2025-09-09T16:06:31Z	-
dc.date.available	2025-09-10	-
dc.date.copyright	2025-09-09	-
dc.date.issued	2025	-
dc.date.submitted	2025-08-08	-
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dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/99346	-
dc.description.abstract	非小兒麻痺腸病毒中，特別是腸病毒A71型及腸病毒D68型，近年來因與全球急性無力脊髓炎的高度發生率及兒童高度死亡率相關，已成為臨床上極具重要性的病原體。鑑於黏膜表面在抵禦病毒初期入侵中扮演至關重要的角色，鼻腔疫苗因其可同時誘導局部及全身性黏膜免疫被認為是一個有前景的病原體預防策略。然而，鼻腔疫苗因其抗原往往無法突破黏膜免疫耐受性，以及產生持久且具保護力的記憶性免疫反應，使得其有效性受到很大限制。而酵母聚醣是一種酵母菌細胞壁的多醣成分，已知可與多種模式識別受體相互作用，協調先天性及適應性免疫反應。此外，其佐劑的潛力已在多個病毒疫苗模型中得到證實。在本研究中，我們旨在評估酵母聚醣作為腸病毒雙價鼻腔疫苗佐劑的應用性。首先，我們分離並培養小鼠骨髓來源的樹突細胞，並於體外觀察有酵母聚醣存在的條件下其先天性免疫之刺激效應。透過誘導多種細胞激素的產生，顯示酵母聚醣在體外對骨髓來源的樹突細胞具有強效的活化能力。接著，我們製備兩種分別針對腸病毒A71型及腸病毒D68型的單價去活化疫苗，並加入酵母聚醣作為佐劑，經由鼻腔途徑多次給予C57BL/6小鼠，以研究其免疫調節作用。在三劑疫苗接種過後，酵母聚醣能顯著增強兩種疫苗在C57BL/6小鼠體內的免疫原性，包括誘導多個黏膜部位產生大量病毒特異性免疫球蛋白A、有效提高血清中和抗體的效價，以及促進抗原再刺激後脾臟中免疫球蛋白A產生性B細胞與白血球介素-17產生性T細胞的增生。此外，我們亦開發了含有酵母聚醣作為佐劑的腸病毒雙價疫苗，以驗證其在雙價疫苗中的效果。與單價疫苗結果一致，三次鼻腔的疫苗接種過後，以酵母聚醣作為佐劑能有效促進鼻黏膜病毒特異性免疫球蛋白A反應，同時誘發強勁的脾臟次級免疫反應。值得注意的是，酵母聚醣在雙價疫苗中的免疫增強效果在針對腸病毒D68型的特異性免疫中表現得更為顯著。最後，我們使用兩種新生小鼠的腸病毒感染模型，評估含有酵母聚醣作為佐劑的單價及雙價腸病毒鼻黏膜疫苗的保護效果。在hSCARB2基因轉殖的新生小鼠中，在兩劑單價腸病毒A71型鼻黏膜疫苗接種過後，酵母聚醣作為佐劑於感染腸病毒A71型致死劑量後顯著提高了疫苗的保護效果，表現為提高的感染存活率、減輕的臨床症狀並減少肌肉組織的病理損傷。在ICR新生小鼠中，接受來自三次含有酵母聚醣作為佐劑之雙價腸病毒鼻黏膜疫苗接種供體的被動轉移血清後，不論是感染腸病毒A71型或是D68型致死劑量後均表現出延長的存活時間、較輕的臨床症狀及目標組織中較低的病毒載量。總結而言，我們的研究結果支持以酵母聚醣作為腸病毒鼻腔疫苗佐劑的潛在應用，該策略為增強新生兒對腸病毒A71型及腸病毒D68型嚴重感染的防護效果提供了可行的方案，並推動鼻黏膜疫苗的蓬勃發展。	zh_TW
dc.description.abstract	Non-polio enteroviruses, particularly EV-A71 and EV-D68, have become clinically significant in recent years due to their association with high frequencies of acute flaccid myelitis (AFM) and significant pediatric mortality worldwide. Given the critical role of mucosal surfaces in defending initial viral entry, intranasal vaccines have been proposed as a promising strategy to elicit both local and systemic mucosal immunity. However, the effectiveness of intranasal vaccines has been limited, as the antigens often fail to break mucosal tolerance and generate durable and protective memory responses. Zymosan, a yeast-derived cell wall component, is known to interact with multiple pattern recognition receptors (PRRs), coordinating both innate and adaptive immune responses. In addition, its adjuvant potential has been demonstrated in several viral vaccine models. In this study, we aimed to assess the applicability of zymosan as an adjuvant in an intranasal bivalent enterovirus vaccine. Initially, bone marrow-derived dendritic cells (BMDCs) were isolated and cultured in the presence of zymosan to evaluate its innate immunostimulatory effects. By inducing various cytokine productions, zymosan demonstrated potent activation of BMDCs in vitro. Subsequently, two inactivated monovalent vaccines targeting EV-A71 and EV-D68 were formulated with zymosan and administered intranasally to C57BL/6 mice to investigate the immunomodulatory effects of zymosan. Following a three-dose immunization regimen, zymosan significantly enhanced vaccine immunogenicity in vivo. This included robust induction of virus-specific IgA at multiple mucosal sites, elevated serum neutralizing antibody titers, and expansions of splenic IgA-producing B cells and IL-17-producing T cells upon antigen restimulation. Moreover, an EV-A71/EV-D68 bivalent vaccine with zymosan adjuvantation was developed to validate these findings in a bivalent vaccine setting. Consistent with the monovalent results, triple intranasal vaccination induced strong mucosal IgA responses, particularly at the nasal mucosa, as well as potent splenic secondary responses. Notably, the immunoenhancing effects of zymosan were more prominent in the context of EV-D68-specific immunity. Finally, two neonatal mouse models were employed to evaluate the protective efficacy of the zymosan-adjuvanted vaccines. In hSCARB2 transgenic neonatal mice, double vaccination with EV-A71 and zymosan significantly improved survival rates, mitigated clinical manifestations, and reduced histopathological damage following lethal EV-A71 challenge. In neonatal ICR mice, passive transfer of sera from zymosan-adjuvanted triple-vaccinated donors conferred significant protection to recipient mice, as evidenced by prolonged survival, reduced clinical severity, and decreased viral loads in target tissues. In summary, our findings support the application of zymosan as a potent nasal adjuvant in enterovirus vaccine formulations. This approach offers a viable strategy for enhancing early-life protection against severe EV-A71 and EV-D68 infections and contributes to the advancement of nasal spray-based vaccination platforms.	en
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dc.description.tableofcontents	Table of Contents 博士論文口試委員審定書 i 謝誌 ii 摘要 iv Abstract vi I. Introduction 1 1. Enteroviruses: morphology features and replication strategies 2 2. Non-polio enteroviruses: EV-A71 and EV-D68 3 2-1 Epidemiology and clinical significance 4 2-2 Transmission: viral tropism and neuroinvasion 7 3. Therapeutic and preventive strategies 12 4. Zymosan: a PAMP adjuvant candidate in intranasal vaccination 14 5. Specific aims 16 II. Materials and Methods 19 1. Experimental animals 20 2. Cultured BMDC generations 20 3. Profile of CLR expressions in BMDCs 21 4. BMDC treatments 24 5. Virus and vaccine preparations 25 6. Mouse immunizations 27 7. Sample collections 28 8. Measurements of antigen-specific antibody responses 29 9. Neutralization assays 30 10. Enzyme-linked immunospot (ELISPOT) assays 31 11. Splenic response analyses 32 12. Serum transfer assays 34 13. In vivo protection assays 35 14. Histopathological staining 36 15. Determination of viral loads in tissues 36 16. Statistical analyses 37 III. Results 38 1. The high expressions of dectin-1 and MGL-2 in BMDCs made them the primary target of the PAMP adjuvants in our study. 39 2. Zymosan showed superior immuno-inducibility by promoting cytokine releases from BMDCs. 39 3. Zymosan incorporation into an intranasal EV-A71 vaccine as an adjuvant substantially increased specific mucosal immunity after triple vaccination. 40 4. Zymosan adjuvantation in the intranasal EV-A71 vaccine induced the production of serum antibodies with significant neutralizing ability. 42 5. Zymosan adjuvantation in the intranasal EV-A71 vaccine significantly enhanced splenic memory responses upon antigen reencounter. 44 6. Passive transfer of immunized sera to neonatal ICR mice significantly prevented the severe infection by EV-A71 (MP4). 46 7. Zymosan adjuvantation in the intranasal EV-A71 vaccine did not significantly enhance humoral immune responses in neonatal hSCARB2 transgenic mice but markedly attenuated their weight loss after a lethal EV-A71 challenge. 48 8. Zymosan exerted its adjuvanticity on improving the protective efficacy of the intranasal EV-A71 vaccine in the neonatal hSCARB2 transgenic mice against a lethal viral challenge 50 9. The intranasal priming in double EV-D68 vaccination could lead to enhanced both primary antibody responses and secondary immune responses 53 10. Zymosan adjuvantation in the intranasal EV-D68 vaccine enhanced humoral responses after triple vaccination. 55 11. Zymosan adjuvantation in the intranasal EV-D68 vaccine promoted splenic IL-17 production upon antigen restimulation. 56 12. Passive transfer of immunized sera to neonatal ICR mice significantly prevented the severe infection by EV-D68. 58 13. Zymosan adjuvantation in the intranasal enterovirus bivalent vaccine promoted the antigen-specific antibody responses after triple intranasal immunization. 62 14. Zymosan adjuvantation in the intranasal enterovirus bivalent vaccine significantly enhanced splenic memory responses upon subsequent antigen restimulations. 64 15. Passive transfer of sera from subjects immunized with the bivalent enterovirus vaccine significantly protected neonatal ICR mice against severe enterovirus infections, with sera from the zymosan-adjuvanted group providing superior passive protection specifically against EV-D68. 65 IV. Discussions 69 V. Conclusion and Prospects 83 VI. References 85 VII. Figures 97 Table of Figures Figure 1. Dectin-1 and MGL-2 were distinguished from the other common CLRs as the primary target of the PAMP adjuvant due to their high expression level in BMDCs. 99 Figure 2. Zymosan, a dectin-1 agonist, efficiently induced innate activation by promoting instructive cytokine production from BMDCs. 102 Figure 3. Triple intranasal immunization had minimal effect on the body weight of mice throughout the observation period. 105 Figure 4. Triple intranasal immunization with inactivated EV-A71 and zymosan significantly enhanced virus-specific antibody responses across various mucosae in mature C57BL/6 mice 107 Figure 5. Triple intranasal immunization with inactivated EV-A71 and zymosan induced serum antibodies with significant neutralizing ability. 109 Figure 6. Triple intranasal immunization with inactivated EV-A71 and zymosan significantly recalled the secretion of virus-specific IgA in splenocytes upon antigen restimulation. 112 Figure 7. Triple intranasal immunization with inactivated EV-A71 and zymosan significantly enhanced splenocyte proliferation and IL-17 production upon antigen reencounter. 114 Figure 8. The effect of host age and challenge dose on disease severity of the neonatal EV-A71 (MP4)-induced disease mouse model 116 Figure 9. Passive transfer of EV-A71-immunized sera to neonatal ICR mice conferred protection against severe EV-A71 (MP4) infection. 118 Figure 10. Double intranasal immunization with inactivated EV-A71 and zymosan effectively protected neonatal hSCARB2+/+ mice from significant body weight loss after a lethal EV-A71 challenge. 121 Figure 11. Double intranasal immunization with inactivated EV-A71 and zymosan significantly extended survival and mitigated clinical symptoms and tissue pathology in neonatal hSCARB2+/+ mice after a lethal EV-A71 challenge. 124 Figure 12. Double intranasal immunization with inactivated EV-A71 and zymosan significantly reduced tissue pathology in neonatal hSCARB2+/+ mice after a lethal EV-A71 challenge. 126 Figure 13. Double intranasal immunization with inactivated EV-D68 significantly induced virus-specific IgA production at multiple mucosae. 128 Figure 14. Double intranasal vaccination with inactivated EV-D68 significantly induced virus-specific IgA production in sera. 130 Figure 15. The intranasal priming in the double EV-D68 vaccination played a critical role in enhancing the recall responses upon antigen reexposure. 132 Figure 16. Triple intranasal immunization with inactivated EV-D68 and zymosan significantly induced virus-specific IgA production at multiple mucosae. 135 Figure 17. Triple intranasal immunization with inactivated EV-D68 and zymosan induced serum antibodies with significant neutralizing ability. 137 Figure 18. Triple vaccination with inactivated EV-D68 and zymosan significantly promoted splenic IL-17 production upon subsequent antigen stimulation 138 Figure 19. The effect of viral strains on disease severity of the neonatal EV-D68-induced disease mouse model 142 Figure 20. The effects of challenge dose, host age, and infection route on disease severity of the neonatal EV-D68-induced disease mouse model 144 Figure 21. The effects of challenge dose and infection route on disease severity of the neonatal EV-D68-induced disease mouse model 147 Figure 22. Passive transfer of EV-D68-immunized sera to neonatal ICR mice conferred protection against severe EV-D68 infection. 150 Figure 23. Triple intranasal immunization with the enterovirus bivalent vaccine plus zymosan significantly induced specific IgA production at multiple mucosae. 152 Figure 24. Triple intranasal immunization with the enterovirus bivalent vaccine plus zymosan induced serum antibodies with significant neutralizing ability. 154 Figure 25. Triple vaccination with the enterovirus bivalent vaccine plus zymosan induced the production of virus-specific antibodies in splenocytes upon antigen reencounter. 156 Figure 26. Triple vaccination with the enterovirus bivalent vaccine plus zymosan significantly promoted splenic IL-17 production upon ex vivo antigen restimulation. 158 Figure 27. Sera transfer from subjects immunized with the enterovirus bivalent vaccination to neonatal ICR mice conferred protection against severe EV-D68 and EV-A71 infection. 160 Figure 28. Sera transfer from subjects immunized with the enterovirus bivalent vaccination to neonatal ICR mice significantly decreased viral loads in susceptible tissues after the lethal challenge of EV-D68 or EV-A71. 162 Figure 29. Intranasal delivery of zymosan significantly boosted antigen-specific immune responses in both the monovalent and combined vaccines, resulting in enhanced passive protection against targeted enteroviruses and increased vaccine efficacy against lethal EV-A71 infection following active immunization. 164	-
dc.language.iso	zh_TW	-
dc.subject	腸病毒A71型	zh_TW
dc.subject	腸病毒D68型	zh_TW
dc.subject	急性無力脊髓炎	zh_TW
dc.subject	鼻黏膜疫苗	zh_TW
dc.subject	病原體相關分子模式佐劑	zh_TW
dc.subject	酵母聚醣	zh_TW
dc.subject	Acute flaccid myelitis (AFM)	en
dc.subject	Enterovirus A71	en
dc.subject	Zymosan	en
dc.subject	PAMP adjuvant	en
dc.subject	Intranasal vaccine	en
dc.subject	Enterovirus D68	en
dc.title	研究以酵母聚醣作為佐劑促進腸病毒A71型與D68型之鼻黏膜疫苗免疫反應	zh_TW
dc.title	Study on the adjuvanticity of zymosan in the intranasal vaccination against enterovirus A71 and D68	en
dc.type	Thesis	-
dc.date.schoolyear	113-2	-
dc.description.degree	博士	-
dc.contributor.oralexamcommittee	邱政洵;張鑾英;張淑媛;林志萱	zh_TW
dc.contributor.oralexamcommittee	Cheng-Hsun Chiu ;Luan-Yi Chang ;Sui-Yuan Chang ;Jr-Shiuan Lin	en
dc.subject.keyword	腸病毒A71型,腸病毒D68型,急性無力脊髓炎,鼻黏膜疫苗,病原體相關分子模式佐劑,酵母聚醣,	zh_TW
dc.subject.keyword	Enterovirus A71,Enterovirus D68,Acute flaccid myelitis (AFM),Intranasal vaccine,PAMP adjuvant,Zymosan,	en
dc.relation.page	164	-
dc.identifier.doi	10.6342/NTU202503648	-
dc.rights.note	同意授權(限校園內公開)	-
dc.date.accepted	2025-08-08	-
dc.contributor.author-college	醫學院	-
dc.contributor.author-dept	免疫學研究所	-
dc.date.embargo-lift	2030-07-17	-
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