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生物大分子重点实验室

王祥喜  博士 研究员 博士生导师  

中科院生物物理所,中科院感染与免疫重点实验室,研究组长

研究方向:病毒入侵、复制与组装分子机制

电子邮件:xiangxi@ibp.ac.cn

电       话:010-64888806

通讯地址:北京市朝阳区大屯路15号(100101)

英文版个人网页:http://english.ibp.cas.cn/sourcedb/rck/EN_xsszmW/202005/t20200519_341377.html

简       历:

  2009  四川大学生物技术专业,获得理学学士学位

  2014  中国科学院生物物理研究所,获得理学博士学位

  2014.07 - 2014.09  中国科学院生物物理研究所,副研究员

  2014.09 - 2016.02  牛津大学,访问学者

  2014.10 - 至今       中国科学院生物物理研究所,研究员

获奖及荣誉:

  2014年  吴瑞奖学金

  2014年  中国科学院青年研究员人才计划

  2015年  青年人才托举工程

  2015年  贝时璋青年生物物理学家奖

  2020年  中国科学院青年科学家奖

  2020年  中源协和生命医学创新奖

  2021年  首届钟南山青年科技创新奖

  2021年  谈家桢生命科学创新奖

  2022年  TR35青年创新奖

  2022年  第十七届中国青年科技奖

社会任职:

研究方向:

  运用低温冷冻电镜、病毒学、细胞生物学等技术方法,从事人类重大疾病直接相关的病毒完整颗粒及病毒与受体、病毒与抗体的超大分子复合物的精细三维结构和相关功能研究,揭示病毒入侵宿主细胞的分子机制和致病机理以及抗病毒药物研究。主要研究方向包括:1.疱疹病毒的复制、组装和运输机制;2.脑炎性黄病毒神经毒力的分子机制;3.非洲猪瘟病毒、新型冠状病毒的免疫机制与疫苗设计。

  1. 疱疹病毒的复制、组装和运输机制

  疱疹病毒是在世界范围内广泛传播的一大类病毒,包含病毒的种类众多,能够感染包括人类在内的多种哺乳动物。疱疹病毒在感染人体后能够引发多种疾病,包括口腔和生殖器疱疹、水痘、带状疱疹,严重的甚至包括多种免疫系统疾病、脑炎以及癌症等。疱疹病毒有着独特的潜伏-再活化机制,疱疹病毒可以关闭其大部分活动状态的基因,只在特定的潜伏阶段打开特定的少数基因,并在合适的条件下恢复活性,重新进入增殖过程。这种潜伏-再活化机制使得疱疹病毒感染产生的疾病难以完全治愈,通常患者会终生携带病毒。同时疱疹病毒又是非常好的“融瘤”和“神经环路示踪”工具,目前已经进入临床应用。本课题组致力于理解疱疹病毒的复制、组装的动态过程,揭示疱疹病毒在宿主细胞的运输和潜伏与再激活分子机理,为有效防治疱疹病毒的感染和人类生命医学技术手段的提高提供理论基础。  

  2. 脑炎性黄病毒神经毒力的分子机制

  黄病毒,是一类具有包膜的单股正链RNA病毒,主要是通过吸血的节肢动物(蚊、蜱、白蛉等) 进行传播的虫媒病毒,能够广泛引起人类很多重大传染性疾病,主要包括乙型脑炎病毒 (JEV)、森林脑炎病毒、登革热病毒、寨卡病毒和黄热病毒等。黄病毒科中有一大类病毒能够直接入侵脑部而引起的颅内急性炎症,即:病毒性脑炎。本课题组聚焦脑炎性黄病毒神经毒力的分子机制。

  3. 非洲猪瘟病毒、新型冠状病毒免疫机制及疫苗设计;

  疫苗主要通过免疫原和佐剂诱发机体体液与细胞免疫反应,产生中和性抗体等保护物质,当机体再次接触到这种病原体时,机体快速启动其免疫系统进行中和、杀伤病原体。传统的疫苗包括减毒活疫苗、灭活疫苗、载体疫苗、亚单位疫苗等,能够有效保护多种传染性疾病,然而对于某些传染病,如:艾滋、登革热、呼吸道合胞体病毒肺炎等无效。新技术路线的疫苗,如:mRNA疫苗、纳米颗粒候选疫苗等展现出研发周期短,快速、高效诱导、长期保护、个性化升级等优势,具有前景。新型疫苗研发的核心在于设计理念,建立在一定的基础研究上,在体内或体外表达出稳定且构象正确的免疫原,诱导出充足量的中和性抗体。最佳的免疫是产生多种不同类别的中和性抗体(中和抗体多样性),靶向不同的表位,采用不同的中和机制而发挥其高效抑制作用,还能抵抗病毒局部位点突变引发疫苗失效的风险。然而未经设计的免疫原只能诱导出部分中和性抗体,尤其是记忆性抗体比例更低。系统性研究多种中和性抗体的识别表位、中和效价、中和机制、记忆性关联及母系生成机制等科学问题,基于其结构特征、免疫特性等反向、靶向改造免疫原,将关键特异性(或广谱性)抗原表位、记忆性及T细胞杀伤表位等信号进行逐级放大增强,屏蔽或大幅度降低无效的机体免疫反应,提高机体“精准”免疫应答的效率,进而产生广谱、高效且长期的保护。为探索精准疫苗学提供新理论。

承担项目情况:

代表论著:

2022年度

1. Cui Z#, Liu P#, Wang N#, Wang L#, Fan K#, Zhu Q#, Wang K#, Chen R, Feng R, Jia Z, Yang M, Xu G, Zhu B, Fu W, Chu T, Feng L, Wang Y, Pei X, Yang P, Xie XS, Cao L*, Cao Y*, Wang X*. Structural and functional characterizations of infectivity and immune evasion of SARS-CoV-2 Omicron, Cell, 2022, 185(5): 860-871

2. Wang K#, Jia Z#, Bao L#, Wang L#, Cao L#, Chi H#, Hu Y#, Li Q#, Jiang Y, Zhu Q, Deng Y, Liu P, Wang N, Wang L, Liu M, Li Y, Zhu B, Fan K, Fu W, Yang P, Pei X, Cui Z, Qin L, Ge P, Wu J, Liu S, Chen Y, Huang W, Qin CF*, Wang Y*, Qin C*, Wang X*. Memory B cell repertoire from triple vaccinees against diverse SARS-CoV-2 variants, Nature, 2022, 603(7903): 919-925

3. Xiong Q#, Cao L#, Ma C#, Tortorici M#, Liu C, Si J, Liu P, Gu M, Walls A, Wang C, Shi L, Tong F, Huang M, Li J, Zhao C, Shen C, Chen Y, Zhao H, Lan K, Corti D, Veesler D*, Wang X*, Yan H*. Close relatives of MERS-CoV in bats use ACE2 as their functional receptors, Nature, 2022, 612(7941):748-757

4. Cao Y#, Yisimayi A#, Jian F#, Song W#, Xiao T#, Wang L#, Du S#, Wang J#, Li Q#, Chen X#, Yu Y#, Wang P, Zhang Z, Liu P, An R, Hao X, Wang Y, Wang J, Feng R, Sun H, Zhao L, Zhang W, Zhao D, Zheng J, Yu L, Li C, Zhang N, Wang R, Niu X, Yang S, Song X, Chai Y, Hu Y, Shi Y, Zheng L, Li Z, Gu Q, Shao F, Huang W, Jin R, Shen Z*, Wang Y*, Wang X*, Xiao J*, Xie XS*. BA.2.12.1, BA.4 and BA.5 escape antibodies elicited by Omicron infection, Nature, 2022, 608(7923): 593-602

5.Yue C#, Song W#, Wang L, Jian F, Chen X, Gao F, Shen Z, Wang Y, Wang X*, Cao Y*. Enhanced transmissibility of XBB.1.5 is contributed by both strong ACE2 binding and antibody evasion, Lancet Infectious Diseases, 2022, accepted

6. Zhang Y#, Liang D#, Yuan F, Yan Y, Wang Z, Liu P, Yu Q, Zhang X, Wang X*, Zheng A*. Replication is the key barrier during the dual-host adaptation of mosquito-borne flaviviruses, PNAS, 2022, 119(12): e2110491119

7. Cao Y#*, Song W#, Wang L#, Liu P#, Yue C#, Jian F#, Yu Y, Yisimayi A, Wang P, Wang Y, Zhu Q, Deng J, Fu W, Yu L, Zhang N, Wang J, Xiao T, An R, Wang J, Liu L, Zhang N, Wang J, Xiao T, An R, Wang J, Liu L, Yang S, Niu X, Gu Q, Shao F,Hao X,Meng B, Gupta. R, Jin R, Wang Y, Xie X*, Wang X*. Characterization of the enhanced infectivity and antibody evasion of Omicron BA.2.75, Cell host & microbe, 2022, 30: 1-13

8. Wang L#, Fu W#, Bao L#, Jia Z#, Zhang Y#, Zhou Y#, Wu W, Wu J, Zhang Q, Gao Y, Wang K, Wang Q*, Qin C*, Wang X*. Selection and structural bases of potent broadly neutralizing antibodies from 3-dose vaccinees that are highly effective against diverse SARS-CoV-2 variants, including Omicron sublineages, Cell Research, 2022, 32(7):691-694

9. Li Q#, Zhang L#, Liang Z#, Wang N#, Liu S#, Li T, Yu Y, Cui Q, Wu X, Nie J, Wu J, Cui Z, Lu Q, Wang X*, Huang W*, Wang Y*. Cross-reactivity of eight SARS-CoV-2 variants rationally predicts immunogenicity clustering in sarbecoviruses, Signal Transduct Target Ther, 2022 , 7(1): 256

10. Deng W#, Lv Q#, Li F#, Liu J#, Song Z#, Qi F, Wei Q, Yu P, Liu M, Zhou S, Zhang Y, Gao H, Wang N, Jia Z, Gao K, Liu J, Xiao C, Shang H, Wang X*, Bao L*, Qin C*. Sequential immunizations confer cross-protection against variants of SARS-CoV-2, including Omicron in Rhesus macaques,Signal Transduction and Targeted Therapy,2022, 7(1): 124

11. Li X#, Cui Z#,Hang F#, Chen Q#, Cao L#, Qiu H, Zhang N, Xu Y, Zhang R, Zhou C, Ye Q, Deng Y, Guo Y, Qin S, Fan K, Wang L, Jia Z, Cui Y*, Wang X*, Qin C*. A highly immunogenic live-attenuated vaccine candidate prevents SARS-CoV-2 infection and transmission in hamsters, Innovation (N Y), 2022, 3(2): 100221

12. Liu S#, Jia Z#, Nie J#, Liang Z#, Xie J, Wang L, Zhang L, Wang X*, Wang Y*, Huang W*. A broader neutralizing antibody against all the current VOCs and VOIs targets unique epitope of SARS-CoV-2 RBD, Cell Discovery, 2022, 8(1): 81

13. Yang P#, Shi D#, Fu J, Zhang L, Chen R, Zheng B, Wang X, Xu S*, Zhu L*, Wang K*. Atomic Structures of Coxsackievirus B5 Provide Key Information on Viral Evolution and Survival, J Virol, 2022, 96(9): e0010522

14. Chi H#, Wang L#, Liu C#, Cheng X#, Zheng H#, Lv L, Tan Y, Zhang N, Zhao S, Wu M, Luo D, Qiu H, Feng R, Fu W, Zhang J, Xiong X, Zhang Y, Zu S, Chen Q, Ye Q, Yan X, Hu Y, Zhang Z, Yan R, Yin J, Lei P, Wang W, Lang G*, Shao J*, Deng Y*, Wang X*, Qin C*. An Engineered IgG-VHH Bispecific Antibody against SARS-CoV-2 and Its Variants,Small Methods, 2022,6(12): e2200932

15. Wang M#, Sun Z#, Cui C#, Wang S, Yang D, Shi Z, Wei X, Wang P, Sun W, Zhu J, Li J, Du B, Liu Z, Wei L, Liu C, He X, Wang X*, Zhang X*, Wang J*. Structural Insights into Alphavirus Assembly Revealed by the Cryo-EM Structure of Getah Virus, Viruses, 2022, 14(2): 327

2021年度

16. Cao Y#, Wang J#, Jian F#, Xiao T#, Song W#, Yisimayi A#, Huang W#, Li Q, Wang P, An R, Wang J, Wang Y, Niu X, Yang S, Liang H, Sun H, Li T, Yu Y, Cui Q, Liu S, Yang X, Du S, Zhang Z, Hao X, Shao F, Jin R, Wang X*, Xiao J*, Wang Y*, Xie XS*. Omicron escapes the majority of existing SARS-CoV-2 neutralizing antibodies, Nature, 2021, https://doi.org/10.1038/s41586-021-04385-3

17. Guo Q.#, Zhao Y.#, Li J.#, Liu J.#, Yang X.#, Guo X., Kuang M., Xia H., Zhang Z., Cao L., Luo Y., Bao L., Wei X., Deng W., Wang N., Chen L., Chen J., Zhu H., Gao R., Qin, C.*, Wang X.*, You F.*. Induction of alarmin S100A8/A9 mediates activation of aberrant neutrophils in the pathogenesis of COVID-19, Cell Host and Microbe, 2021, https://doi.org/10.1016/ j.chom.2020.12.016

18. Zhu L#, Deng Y#, Zhang R#, Cui Z#, Sun C#, Fan C#, Xing X#, Huang W, Chen Q, Zhang N, Ye, Q, Cao T, Wang N, Wang L, Cao L, Wang H, Kong D, Ma J, Luo C, Zhang Y, Nie J, Sun Y, Lv Z, Shaw N, Li Q, Li X, Hu J, Xie L*, Rao Z*, Wang Y*, Wang X*, Qin C*. Double lock of a potent human therapeutic monoclonal antibody against SARS-CoV-2, National Science Review, 2021, nwaa297

19. Zhang L#, Cao L#, Gao X#, Zheng B#, Deng Y#, Li J#, Feng R, Bian Q, Guo X, Wang N, Qiu H, Wang L, Cui Z, Ye Q, Chen G, Lu K, Chen Y, Chen Y, Pan H, Yu J, Yao W, Zhu B, Chen J, Liu Y, Qin C*, Wang X*, Zhu F*. A proof of concept for neutralizing antibody-guided vaccine design against SARS-CoV-2, National Science Review, 2021, nwab053

20. Sun S#, Gu H#, Cao L#, Chen Q#, Ye Q, Yang G, Li R, Fan H, Deng Y, Song X, Qi Y, Li M, Lan J, Feng R, Guo Y, Zhu N, Qin S, Wang L, Zhang Y, Zhou C, Zhao L, Chen Y, Shen M, Cui Y, Yang X, Wang X, Tan W, Wang H*, Wang X*, Qin C*. Characterization and structural basis of a lethal mouse-adapted SARS-CoV-2, Nat Commun, 2021,12(1), 5654

21. Tai L#, Zhu G#, Yang M#, Cao L, Xing X, Yin G, Chan C, Qin C, Rao Z, Wang X*, Sun F*, Zhu Y*. Nanometer resolution in situ structure of the SARS-CoV-2 postfusion spike protein, PNAS, 2021, 118 (48), e2112703118

22. Zhao Y#, Kuang M#, Li J#, Zhu L#, Jia Z, Guo X, Hu Y, Kong J, Yin H, Wang X*, You F*. SARS-CoV-2 spike protein interacts with and activates TLR4, Cell Research, 2021, 31: 818-820

23. Sun Y#, Wang L#, Feng R#, Wang N#, Wang Y#, Zhu D#, Xing X, Yang P, Zhang Y*, Li W*, Wang X*. Structure-based development of three- and four-antibody cocktails against SARS-CoV-2 via multiple mechanisms, Cell Research, 2021, 31, 597-600

24. Feng R#, Wang L#, Shi D#, Zheng B, Zhang L, Hou H, Xia D, Cui L, Wang X*, Xu S*, Wang K*, Zhu L*. Structural basis for neutralization of an anicteric hepatitis associated echovirus by a potent neutralizing antibody, Cell Discovery, 2021, 7: 35

25. Dong H.#, Liu P.#, Bai M.#, Wang K.#, Feng R.#, Zhu D., Sun Y., Mu S., Li H., Michiel H., Sun, S.*, Wang X.*, Guo H.*. Structural and molecular basis for foot-and-mouth disease virus neutralization by two potent protective antibodies, Protein & Cell, 2021

2020年度

26. Yao H#, Sun Y#, Deng Y#, Wang N#, Tan Y#, Zhang N#, Li X, Kong C, Xu Y, Chen Q, Cao T, Zhao H, Yan X, Cao L, Lv Z, Zhu D, Feng R, Wu N, Zhang W, Hu Y, Chen K, Zhang R, Lv Q, Sun S, Zhou Y, Yan R, Yang G, Sun X, Liu C, Lu X, Cheng L, Qiu H, Huang X, Weng T, Shi D, Jiang W, Shao J, Wang L, Zhang J, Jiang T, Lang G*, Qin C*, Li L*, Wang X*. Rational Development of a Human Antibody Cocktail that Deploys Multiple Functions to Confer Pan-SARS-CoVs Protection, Cell Research, 2020, 10.1038/s41422-020-00444-y

27. Wang N#, Sun Y#, Feng R#, Wang Y#, Guo Y#, Zhang L#, Deng Y, Wang L, Cui Z, Cao L, Zhang Y, Li W*, Zhu F*, Qin C*, Wang X*. Structure-based development of human antibody cocktails against SARS-CoV-2, Cell Research, 2020, 10.1038/s41422-020-00446-w

28. Zhang Y#, Zeng G#, Pan H#, Li C#, Hu Y, Chu K, Han W, Chen Z, Tang R, Yin W, Chen X, Hu Y, Liu X, Jiang C, Li J, Yang M, Song Y, Wang X, Gao Q*, Zhu F*. Safety, tolerability, and immunogenicity of an inactivated SARS-CoV-2 vaccine in healthy adults aged 18-59 years: a randomised, double-blind, placebo-controlled, phase 1/2 clinical trial, The Lancet Infectious Diseases, 2020, 10.1016/ S1473-3099(20)30870-7

29. Lv Z#, Deng Y#, Ye Q#, Cao L#, Sun C#, Fan C#, Huang W, Sun S, Sun Y, Zhu L, Chen Q, Wang N, Nie J, Cui Z, Zhu D, Shaw N, Li X, Li Q, Xie L*, Wang Y*, Rao Z*, Qin C*, Wang X*. Structural basis for neutralization of SARS-CoV-2 and SARS-CoV by a potent therapeutic antibody, Science, 2020, 369(6510):1505-1509

30. Gao Q#, Bao L#, Mao H#, Wang L#, Xu K#, Yang M#, Li Y, Zhu L, Wang N, Zhe Lv, Gao H, Ge X, Kan B, Hu Y, Liu J, Cai F, Jiang D, Yin Y, Qin C, Li J, Gong X, Lou X, Shi W, Wu D, Zhang H, Zhu L, Deng W, Li Y, Lu J*, Li C*, Wang X*, Yin W*, Zhang Y*, Qin Q*. Development of an inactivated vaccine candidate for SARS-CoV-2, Science, 2020,369(6499):77-81

31. Wang K#, Zhu L#, Sun Y#, Li M, Zhao X, Cui L, Zhang L, George F. Gao, Zhai W, Zhu F*, Rao Z, Wang X*. Structures of Echovirus 30 in complex with its receptors inform a rational prediction for enterovirus receptor usage. Nature Communications, 11, 4421 (2020).

32. Wang K#, Zheng B#, Zhang L#, Cui L, Su X, Zhang Q, Guo Z, Guo Y, Zhang W, Zhu L*, Zhu F*, Rao Z*, Wang X*. Serotype specific epitopes identified by neutralizing antibodies underpin immunogenic differences in Enterovirus B. Nature Communications, 11, 4419 (2020)

33. Yang Y#, Yang P#, Wang N, Chen Z, Su D, Zhou ZH, Rao Z*, Wang X*. Architecture of the herpesvirus genome-packaging complex and implications for DNA translocation, Protein & Cell, 11, 339-351 (2020).

34. Wang N#, Chen W#, Zhu L#, Zhu D, Feng R, Wang J, Zhu B, Zhang X, Chen X, Liu X, Yan R, Ni D, Grace Zhou G, Liu H*, Rao Z*, Wang X*. Structures of the portal vertex reveal essential protein-protein interactions for Herpesvirus assembly and maturation. Protein & Cell, 11, 366-373 (2020)

35. Zhang M, Wang Y, He W, Sun Y, Guo Y, Zhong W, Gao Q, Liao M, Wang X, Cai Y*, Guo Y*, and Rao Z. Design, Synthesis, and Evaluation of Novel Enterovirus 71 Inhibitors as Therapeutic Drug Leads for the Treatment of Human Hand, Foot, and Mouth Disease,J. Med. Chem., 2020, 63, 3, 1233-1244

36. Zhao Y, Zhou D, Ni T, Karia D, Kotecha A, Wang X, Rao Z, Jones Y, Fry E.E, Ren J, Stuart D. Hand-foot-and-mouth disease virus receptor KREMEN1 binds the canyon of Coxsackie Virus A10. Nature Communications, 11, 38 (2020).

2019年度

37. Wang N#, Zhao D#, Wang J#, Zhang Y#, Wang M, Gao Y, Li F, Wang J, Bu Z*, Rao Z*, Wang X*. Architecture of African swine fever virus and implications for viral assembly, Science, 2019, 366(6465): 640-644

38. Cao L#, Liu P#, Yang P, Gao Q, Li H, Sun Y, Zhu L, Lin J, Dan S*, Rao Z*, Wang X*. Structural basis for neutralization of hepatitis A virus informs a rational design of highly potent inhibitors, PLoS Biology, 2019,17(4): e3000229

39. Colibus L.D, Roine E, Walter T.S, Ilca S.L, Wang X, Wang N, Roseman A.M, Bamford D., Huiskonen J.T, Stuart D.I. Assembly of complex viruses exemplified by a halophilic euryarchaeal virus, Nature Communications, 10, 1456 (2019).

40. Zhou D, Zhao Y, Kotecha A, Fry E.E, Kelly J.T, Wang X, Rao Z, Rowlands D.J, Ren J, Stuart D.I. Unexpected mode of engagement between enterovirus 71 and its receptor SCARB2. Nature Microbiology, 4, 414-419 (2019).

41. Lu X, Xiao H, Li S, Pang X, Song J, Liu S, Cheng H, Li Y, Wang X, Huang C, Guo T, Ter Meulen J, Daffis S, Yan J, Dai L, Rao Z, Klenk HD, Qi J, Shi Y, Gao GF. Double Lock of a Human Neutralizing and Protective Monoclonal Antibody Targeting the Yellow Fever Virus Envelope. Cell Reports. 2019 Jan 8;26(2):438-446.e5.

2018年度

42. Yuan S#, Wang J#, Zhu D#, Wang N, Gao Q, Chen W, Wang J*, Zhang X*, Liu H*, Rao Z*, Wang X*. Cryo-EM structure of a Herpesvirus capsid at 3.1 Å, Science, 2018, 360 (6384): 48-58

43. Zhu L#*, Sun Y#, Fan J#, Zhu B, Cao L, Gao Q, Zhang Y*, Liu H, Rao Z*, Wang X*. Structures of Coxsackievirus A10 unveil the molecular mechanisms of receptor binding and viral uncoating, Nature Communications, 2018, 9: 4985

44. Wang J#, Yuan S#, Zhu D#, Tang H, Wang N, Chen W, Gao Q, Li Y, Wang J, Liu H*, Zhang X*, Rao Z*, Wang X*. Structure of the herpes simplex virus type 2 C-capsid with capsid-vertex-specific component, Nature Communications, 2018, 9: 3668

45. Qiu X#, Lei Y#, Yang P, Gao Q, Wang N, Cao L, Yuan S, Huang X, Deng Y, Ma W, Ding T, Zhang F, Wu X, Hu J, Liu S, Qin C, Wang X*, Xu Z*, Rao Z*. Structural basis for neutralization of Japanese encephalitis virus by two potent therapeutic antibodies, Nature Microbiology, 2018, 3: 287-294

46. Huo Y#*, Li T, Wang N, Dong Q, Wang X*, Jiang T*. Cryo-EM structure of Type III-A CRISPR effector complex, Cell Research, 2018, 28: 1195-1197

47. Zhu L#, Xu K#, Wang N#, Cao L, Wu J, Gao Q, Fry E.E, Stuart D.I, Rao Z, Wang J, Wang X*. Neutralization Mechanisms of Two Highly Potent Antibodies against Human Enterovirus 71, mBio, 2018, 9: e01013-18

48. Zhu D, Wang X, Fang Q, Van Etten J, Rossmann M.G, Rao Z, Zhang X. Pushing the resolution limit by correcting the Ewald sphere effect in single-particle Cryo-EM reconstructions. Nature Communications, 9, 1552 (2018).

49. Xie DY, Liu ZY, Nian QG, Zhu L, Wang N, Deng YQ, Zhao H, Ji X, Li XF, Wang X, Shi PY, Qin CF. A single residue in the αB helix of the E protein is critical for Zika virus thermostability. Emerging Microbes & Infections. 2018 Jan 24;7(1):5

2017年度及以前

50. Wang X#*, Zhu L#, Dang M#, Hu Z#, Gao Q, Yuan S, Sun Y, Zhang B, Ren J, Kotecha A, Walter T.S, Wang J*. Fry E.E*, Stuart D.I*, Rao Z*, Potent neutralization of hepatitis A virus reveals a receptor mimic mechanism and the receptor recognition site, Proc.Natl.Acad.Sci.USA, 2017, 114: 770~775

51. Wang X#*, Li S#, Zhu L#, Nian Q#, Yuan S, Gao Q, Hu Z, Ye Q, Li X, Xie D, Shaw N, Wang J, Walter T.S, Huiskonen J.T, Fry E.E, Qin C*, Stuart D.I*, Rao Z*. Near-atomic structure of Japanese encephalitis virus reveals critical determinants of virulence and stability, Nature Communications, 2017, 8: 14

52. Yuan L, Huang X, Liu Z, Zhang F, Zhu X, Yu J, Ji X, Xu Y, Li G, Li C, Wang H, Deng Y, Wu M, Cheng M, Ye Q, Xie D, Li X, Wang X, Shi W, Hu B, Shi P, Xu Z, Qin C. A single mutation in the prM protein of Zika virus contributes to fetal microcephaly. Science, 17 2017: 933-936

53. Zhang X#, Yang P#, Wang N, Zhang J, Li J, Guo H, Yin X, Rao Z, Wang X*, Zhang L*. The binding of a monoclonal antibody to the apical region of SCARB2 blocks EV71 infection, Protein & Cell, 2017, 8: 590-600

54. Zhu L#, Wang X#, Ren J, Kotecha A, Walter T.S, Yuan S, Yamashita T, Tuthill T.J, Fry E.E, Rao Z*, Stuart D.I*. Structure of human Aichi virus and implications for receptor binding, Nature Microbiology, 2016, 1: 16150

55. Wang X#, Ren J#, Gao Q#, Hu Z, Sun Y, Li X, Rowlands D.J, Yin W, Wang J*, Stuart D.I*, Rao Z*, Fry E.E. Hepatitis A virus and the origins of picornaviruses, Nature, 2015, 517: 85-88

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(资料来源:王祥喜研究员,2023-01-30)