1.Mechanisms of Intestinal Microecology in Hyperuricemia and Traditional Chinese Medicine Intervention:A Review
Mingyuan FAN ; Jiuzhu YUAN ; Hongyan XIE ; Sai ZHANG ; Qiyuan YAO ; Luqi HE ; Qingqing FU ; Hong GAO
Chinese Journal of Experimental Traditional Medical Formulae 2025;31(5):329-338
In recent years, hyperuricemia (HUA) has shown a rapidly increasing incidence and tends to occur in increasingly young people, with a wide range of cardiac, renal, joint, and cancerous hazards and all-cause mortality associations. Western medicine treatment has limitations such as large liver and kidney damage, medication restriction, and easy recurrence. The intestine is the major extra-renal excretion pathway for uric acid (UA), and the intestinal microecology can be regulated to promote UA degradation. It offers great potential to develop UA-lowering strategies that target the intestinal microecology, which are promising to provide safer and more effective therapeutic approaches. Traditional Chinese medicine (TCM) can treat HUA via multiple targets and multiple pathways from a holistic view, with low toxicity and side effects. Studies have shown that intestinal microecology is a crucial target for TCM in the treatment of HUA. However, its specific mechanism of action has not been fully elucidated. Focusing on the key role of intestinal microecology in HUA, this review explores the relationship between intestinal microecology and HUA in terms of intestinal flora, intestinal metabolites, intestinal UA transporters, and intestinal barriers. Furthermore, we summarize the research progress in TCM treatment of HUA by targeting the intestinal microecology, with the aim of providing references for the development of TCM intervention strategies for HUA and the direction of future research.
2.A Case of Neurofibromatosis Type 1 Complicated with Bilateral Sensorineural Hearing Loss
Ruzhen GAO ; Xinmiao FAN ; Wei GU ; Tengyu YANG ; Zhuhua ZHANG ; Tao WANG ; Mingsheng MA ; Zenan XIA ; Hanhui FU ; Yaping LIU ; Xiaowei CHEN
JOURNAL OF RARE DISEASES 2025;4(3):348-354
Neurofibromatosis type 1 (NF1) presents with a diverse range of symptoms that can affect the skin, bones, eyes, central nervous system, and other organs. This article reports the diagnosis and treatment process of a patient with NF1 complicated by bilateral severe-to-profound sensorineural hearing loss. Genetic testing revealed a heterozygous variant of
3.Chinese expert consensus on blood support mode and blood transfusion strategies for emergency treatment of severe trauma patients (version 2024)
Yao LU ; Yang LI ; Leiying ZHANG ; Hao TANG ; Huidan JING ; Yaoli WANG ; Xiangzhi JIA ; Li BA ; Maohong BIAN ; Dan CAI ; Hui CAI ; Xiaohong CAI ; Zhanshan ZHA ; Bingyu CHEN ; Daqing CHEN ; Feng CHEN ; Guoan CHEN ; Haiming CHEN ; Jing CHEN ; Min CHEN ; Qing CHEN ; Shu CHEN ; Xi CHEN ; Jinfeng CHENG ; Xiaoling CHU ; Hongwang CUI ; Xin CUI ; Zhen DA ; Ying DAI ; Surong DENG ; Weiqun DONG ; Weimin FAN ; Ke FENG ; Danhui FU ; Yongshui FU ; Qi FU ; Xuemei FU ; Jia GAN ; Xinyu GAN ; Wei GAO ; Huaizheng GONG ; Rong GUI ; Geng GUO ; Ning HAN ; Yiwen HAO ; Wubing HE ; Qiang HONG ; Ruiqin HOU ; Wei HOU ; Jie HU ; Peiyang HU ; Xi HU ; Xiaoyu HU ; Guangbin HUANG ; Jie HUANG ; Xiangyan HUANG ; Yuanshuai HUANG ; Shouyong HUN ; Xuebing JIANG ; Ping JIN ; Dong LAI ; Aiping LE ; Hongmei LI ; Bijuan LI ; Cuiying LI ; Daihong LI ; Haihong LI ; He LI ; Hui LI ; Jianping LI ; Ning LI ; Xiying LI ; Xiangmin LI ; Xiaofei LI ; Xiaojuan LI ; Zhiqiang LI ; Zhongjun LI ; Zunyan LI ; Huaqin LIANG ; Xiaohua LIANG ; Dongfa LIAO ; Qun LIAO ; Yan LIAO ; Jiajin LIN ; Chunxia LIU ; Fenghua LIU ; Peixian LIU ; Tiemei LIU ; Xiaoxin LIU ; Zhiwei LIU ; Zhongdi LIU ; Hua LU ; Jianfeng LUAN ; Jianjun LUO ; Qun LUO ; Dingfeng LYU ; Qi LYU ; Xianping LYU ; Aijun MA ; Liqiang MA ; Shuxuan MA ; Xainjun MA ; Xiaogang MA ; Xiaoli MA ; Guoqing MAO ; Shijie MU ; Shaolin NIE ; Shujuan OUYANG ; Xilin OUYANG ; Chunqiu PAN ; Jian PAN ; Xiaohua PAN ; Lei PENG ; Tao PENG ; Baohua QIAN ; Shu QIAO ; Li QIN ; Ying REN ; Zhaoqi REN ; Ruiming RONG ; Changshan SU ; Mingwei SUN ; Wenwu SUN ; Zhenwei SUN ; Haiping TANG ; Xiaofeng TANG ; Changjiu TANG ; Cuihua TAO ; Zhibin TIAN ; Juan WANG ; Baoyan WANG ; Chunyan WANG ; Gefei WANG ; Haiyan WANG ; Hongjie WANG ; Peng WANG ; Pengli WANG ; Qiushi WANG ; Xiaoning WANG ; Xinhua WANG ; Xuefeng WANG ; Yong WANG ; Yongjun WANG ; Yuanjie WANG ; Zhihua WANG ; Shaojun WEI ; Yaming WEI ; Jianbo WEN ; Jun WEN ; Jiang WU ; Jufeng WU ; Aijun XIA ; Fei XIA ; Rong XIA ; Jue XIE ; Yanchao XING ; Yan XIONG ; Feng XU ; Yongzhu XU ; Yongan XU ; Yonghe YAN ; Beizhan YAN ; Jiang YANG ; Jiangcun YANG ; Jun YANG ; Xinwen YANG ; Yongyi YANG ; Chunyan YAO ; Mingliang YE ; Changlin YIN ; Ming YIN ; Wen YIN ; Lianling YU ; Shuhong YU ; Zebo YU ; Yigang YU ; Anyong YU ; Hong YUAN ; Yi YUAN ; Chan ZHANG ; Jinjun ZHANG ; Jun ZHANG ; Kai ZHANG ; Leibing ZHANG ; Quan ZHANG ; Rongjiang ZHANG ; Sanming ZHANG ; Shengji ZHANG ; Shuo ZHANG ; Wei ZHANG ; Weidong ZHANG ; Xi ZHANG ; Xingwen ZHANG ; Guixi ZHANG ; Xiaojun ZHANG ; Guoqing ZHAO ; Jianpeng ZHAO ; Shuming ZHAO ; Beibei ZHENG ; Shangen ZHENG ; Huayou ZHOU ; Jicheng ZHOU ; Lihong ZHOU ; Mou ZHOU ; Xiaoyu ZHOU ; Xuelian ZHOU ; Yuan ZHOU ; Zheng ZHOU ; Zuhuang ZHOU ; Haiyan ZHU ; Peiyuan ZHU ; Changju ZHU ; Lili ZHU ; Zhengguo WANG ; Jianxin JIANG ; Deqing WANG ; Jiongcai LAN ; Quanli WANG ; Yang YU ; Lianyang ZHANG ; Aiqing WEN
Chinese Journal of Trauma 2024;40(10):865-881
Patients with severe trauma require an extremely timely treatment and transfusion plays an irreplaceable role in the emergency treatment of such patients. An increasing number of evidence-based medicinal evidences and clinical practices suggest that patients with severe traumatic bleeding benefit from early transfusion of low-titer group O whole blood or hemostatic resuscitation with red blood cells, plasma and platelet of a balanced ratio. However, the current domestic mode of blood supply cannot fully meet the requirements of timely and effective blood transfusion for emergency treatment of patients with severe trauma in clinical practice. In order to solve the key problems in blood supply and blood transfusion strategies for emergency treatment of severe trauma, Branch of Clinical Transfusion Medicine of Chinese Medical Association, Group for Trauma Emergency Care and Multiple Injuries of Trauma Branch of Chinese Medical Association, Young Scholar Group of Disaster Medicine Branch of Chinese Medical Association organized domestic experts of blood transfusion medicine and trauma treatment to jointly formulate Chinese expert consensus on blood support mode and blood transfusion strategies for emergency treatment of severe trauma patients ( version 2024). Based on the evidence-based medical evidence and Delphi method of expert consultation and voting, 10 recommendations were put forward from two aspects of blood support mode and transfusion strategies, aiming to provide a reference for transfusion resuscitation in the emergency treatment of severe trauma and further improve the success rate of treatment of patients with severe trauma.
4.Practice and effect of construction of rational drug use mode of PIVAS by the activities of quality control circle
Yun LU ; Gao WU ; Peng FU ; Yisheng FAN ; Ting YANG ; Shanshan LIU
Journal of Pharmaceutical Practice 2023;41(9):566-571
Objective To establish a rational drug use model of PIVAS and promote the rational drug use in clinical practices by enhancing the quality of prescription review by pharmacists. Methods The PIVAS physician orders received from 2014 to 2021 were extracted through the hospital information management (HIS) system. The types of irrational physician orders were statistically analyzed, the improvements were made by the method of quality control circle (QCC). Results The model of PIVAS rational drug use formed a standardized process. The proficiency of physician order review was improved. From 2014 to 2021, the number and proportion of unreasonable physician orders in PIVAS decreased year by year. Every type of unreasonable physician orders was improved year by year. Conclusion The professional and technical levels of pharmacist for physician order review at our hospital were improved by the model of PIVAS rational drug use. The quality of pharmaceutical service was significantly improved which ensured the safety of patients' medication.
5.Distribution of pathogenic bacteria of bloodstream infection after chemotherapy in patients with acute leukemia and risk factors analysis of the occurrence of adverse events and prediction model construction
Wangyang LI ; Yu FU ; Yanping YANG ; Hai LIN ; Hongqiong FAN ; Qiuju LIU ; Sujun GAO ; Yehui TAN
Journal of Leukemia & Lymphoma 2023;32(7):394-399
Objective:To investigate the distribution of pathogenic bacteria of bloodstream infection after chemotherapy in patients with acute leukemia (AL), to analyze the risk factors for the occurrence of adverse events and to construct a nomogram model to predict the occurrence of adverse events.Methods:The clinical data of 313 AL patients with bloodstream infection who were admitted to the First Hospital of Jilin University from January 2018 to December 2020 were retrospectively analyzed, and the incidence, fatality and distribution characteristics of pathogenic bacteria after chemotherapy in AL patients were analyzed; the occurrence of adverse events (death or infectious shock) in patients with different clinicopathological characteristics were compared. Unconditional logistic binary regression model multifactor analysis was used to screen independent risk factors for the occurrence of adverse events in AL patients with bloodstream infection after chemotherapy; the nomogram model for predicting the occurrence of adverse events was developed by using R software; the Hosmer-Lemeshow test was used to verify the predictive effect of the model.Results:Of the 313 AL patients, the overall fatality rate was 4.2% (13/313), the all-cause fatality rate of bloodstream infection was 3.5% (11/313). Of the 313 cases, 254 cases (81.1%) were Gram-negative bacteria infection, mainly including 115 cases (45.3%) of Escherichia coli, 80 cases (31.5%) of Klebsiella pneumoniae, and 29 cases (11.4%) of Pseudomonas aeruginosa, and 10 cases (3.9%) died; 51 cases (16.3%) were Gram-positive cocci infection, mainly including 22 cases (43.1%) of Streptococcus spp., 20 cases (39.2%) of Staphylococcus spp., 7 cases (13.7%) of Enterococcus faecalis, and 0 case died; 8 cases (2.6%) were fungal infection, including 4 cases (1.3%) of Candida tropicalis, 2 cases (0.6%) of Candida subsmoothis, 1 case (0.3%) of Candida smooth, 1 case (0.3%) of new Cryptococcus, and 3 cases (37.5%) died. The differences in the occurrence rates of adverse events were statistically significant when comparing different treatment stage, risk stratification, timing of sensitive antibiotic use, total duration of fever, and glucocorticoid use in chemotherapy regimen, infecting bacteria carbapenem resistance, and leukemia remission (all P < 0.05). The results of logistic binary regression analysis showed that the use of glucocorticoid in chemotherapy regimen, the total duration of fever ≥7 d, the timing of sensitive antibiotic use ≥24 h, and carbapenem resistance of the infecting bacteria were independent risk factors for the occurrence of adverse events in AL patients with bloodstream infection after chemotherapy (all P < 0.05). A nomogram prediction model for the occurrence of adverse events in AL patients with bloodstream infection was established, and the nomogram model was calibrated and validated with good calibration and discrimination. Conclusions:The pathogenic bacteria of bloodstream infection after chemotherapy in AL patients is mainly Gram-negative bacteria, and the presence of glucocorticoid in chemotherapy regimen, long total duration of fever, poor timing of sensitive antibiotics, and infecting bacteria carbapenem resistance are risk factors for the occurrence of adverse events in AL patients with bloodstream infection after chemotherapy, and the nomogram prediction model based on these factors has a reliable predictive ability for the occurrence of adverse events.
6.Investigation and analysis of airborne allergenic pollen in 4 districts and 5 counties of Hohhot City.
Hui Yu NING ; Hui Jiao CAI ; Ting Ting MA ; Chang E FAN ; Dong Dong WU ; Feng Ying GAO ; Fan KONG ; Fu Jun ZHANG ; Rong WANG ; Hui Hui GUO ; Run Lan MA ; Cai Ying ZHENG ; Bo HAO ; Hong Tian WANG ; Jun Jing ZHANG ; Luo ZHANG ; Xue Yan WANG
Chinese Journal of Preventive Medicine 2023;57(9):1364-1372
Objective: To investigate the species, concentration and seasonal trends of main airborne allergenic pollen in 4 districts and 5 counties of Hohhot City. Methods: The Department of allergy, Beijing Shijitan Hospital Affiliated to Capital Medical University conducted a cross-sectional study about monitoring the airborne allergenic pollen from August 1, 2021 to July 31, 2022 by the gravitational method in 4 districts and 5 counties of Hohhot City, which include Yuquan District, Xincheng District, Huimin District, Saihan District, Tuoketuo County, Helingeer County, Tumotezuoqi County, Wuchuan County and Qingshuihe County. Daily pollens were counted and identified by optical microscopy, and the data were analyzed. Results: The airborne allergenic pollen was collected every month all year round in 4 districts and 5 counties of Hohhot city. Through the whole year of the total quantity of pollens ranged from 24 850 to 50 154 grains per 1 000 mm2 and two peaks of pollen concentration in air were observed,which happened in spring (from March to May) and in summer and autumn (from July to September). In spring, the main pollens were tree pollens, which principally distributed in Populus pollen (18.29%), Ulmus pollen (8.36%), Pinus pollen (6.20%), Cupressaceae pollen (5.23%), Betulaceae pollen (2.73%), Salix pollen (1.80%) and Quercus pollen (1.16%). In summer and autumn, the main pollens were weed pollens, which mainly included Artemisia pollen (42.73%), Chenopodiaceae pollen or Amaranthaceae pollen (7.46%), Poaceae pollen (2.26%), Humulus pollen or Cannabis pollen (0.60%). Conclusion: There were two peaks of main airborne allergenic pollen in 4 districts and 5 counties of Hohhot City. In the spring peak of pollen, the main airborne pollens were tree pollens. In the summer and autumn peak of pollen, the main airborne pollens were weed pollens. The Artemisia pollen was the most major airborne pollen in this area.
Humans
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Cross-Sectional Studies
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Pollen
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Hospitals
7.Investigation and analysis of airborne allergenic pollen in 4 districts and 5 counties of Hohhot City.
Hui Yu NING ; Hui Jiao CAI ; Ting Ting MA ; Chang E FAN ; Dong Dong WU ; Feng Ying GAO ; Fan KONG ; Fu Jun ZHANG ; Rong WANG ; Hui Hui GUO ; Run Lan MA ; Cai Ying ZHENG ; Bo HAO ; Hong Tian WANG ; Jun Jing ZHANG ; Luo ZHANG ; Xue Yan WANG
Chinese Journal of Preventive Medicine 2023;57(9):1364-1372
Objective: To investigate the species, concentration and seasonal trends of main airborne allergenic pollen in 4 districts and 5 counties of Hohhot City. Methods: The Department of allergy, Beijing Shijitan Hospital Affiliated to Capital Medical University conducted a cross-sectional study about monitoring the airborne allergenic pollen from August 1, 2021 to July 31, 2022 by the gravitational method in 4 districts and 5 counties of Hohhot City, which include Yuquan District, Xincheng District, Huimin District, Saihan District, Tuoketuo County, Helingeer County, Tumotezuoqi County, Wuchuan County and Qingshuihe County. Daily pollens were counted and identified by optical microscopy, and the data were analyzed. Results: The airborne allergenic pollen was collected every month all year round in 4 districts and 5 counties of Hohhot city. Through the whole year of the total quantity of pollens ranged from 24 850 to 50 154 grains per 1 000 mm2 and two peaks of pollen concentration in air were observed,which happened in spring (from March to May) and in summer and autumn (from July to September). In spring, the main pollens were tree pollens, which principally distributed in Populus pollen (18.29%), Ulmus pollen (8.36%), Pinus pollen (6.20%), Cupressaceae pollen (5.23%), Betulaceae pollen (2.73%), Salix pollen (1.80%) and Quercus pollen (1.16%). In summer and autumn, the main pollens were weed pollens, which mainly included Artemisia pollen (42.73%), Chenopodiaceae pollen or Amaranthaceae pollen (7.46%), Poaceae pollen (2.26%), Humulus pollen or Cannabis pollen (0.60%). Conclusion: There were two peaks of main airborne allergenic pollen in 4 districts and 5 counties of Hohhot City. In the spring peak of pollen, the main airborne pollens were tree pollens. In the summer and autumn peak of pollen, the main airborne pollens were weed pollens. The Artemisia pollen was the most major airborne pollen in this area.
Humans
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Cross-Sectional Studies
;
Pollen
;
Hospitals
8.Chinese experts′ consensus statement on diagnosis, treatment and prevention of Group A Streptococcus infection related diseases in children
Dingle YU ; Qinghua LU ; Yuanhai YOU ; Hailin ZHANG ; Min LU ; Baoping XU ; Gang LIU ; Lin MA ; Yunmei LIANG ; Ying LIU ; Yaoling MA ; Yanxia HE ; Kaihu YAO ; Sangjie YU ; Hongmei QIAO ; Cong LIU ; Xiaorong LIU ; Jianfeng FAN ; Liwei GAO ; Jifeng YE ; Chuanqing WANG ; Xiang MA ; Jianghong DENG ; Gen LU ; Huanji CHENG ; Wenshuang ZHANG ; Peiru XU ; Jun YIN ; Zhou FU ; Hesheng CHANG ; Guocheng ZHANG ; Yuejie ZHENG ; Kunling SHEN ; Yonghong YANG
Chinese Journal of Applied Clinical Pediatrics 2022;37(21):1604-1618
Group A Streptococcus (GAS) is a very important pathogen, especially for children.On a global scale, GAS is an important cause of morbidity and mortality.But the burden of disease caused by GAS is still unknown in China and also has not obtained enough attention.For this purpose, the expert consensus is comprehensively described in diagnosis, treatment and prevention of GAS diseases in children, covering related aspects of pneumology, infectiology, immunology, microbiology, cardiology, nephrology, critical care medicine and preventive medicine.Accordingly, the consensus document was intended to improve management strategies of GAS disease in Chinese children.
9.Characteristics of abdominal hemorrhage in patients with severe acute pancreatitis and its influence on outcomes
Bao FU ; Zhonghong FAN ; Fei GAO ; De SU ; Jie HU ; Zhengguang GENG ; Xiaoyun FU
Chinese Critical Care Medicine 2022;34(1):70-74
Objective:To explore the risk factors of abdominal hemorrhage (AH) in patients with severe acute pancreatitis (SAP) and its impact on outcome.Methods:The clinical data of 231 SAP patients admitted to Diagnosis and Treatment Center for SAP of Guizhou Province from January 1, 2015 to December 31, 2019 were retrospectively analyzed. These patients were divided into AH group and non-AH group. The general information, etiology, acute physiology and chronic health evaluation Ⅱ (APACHE Ⅱ) score, sequential organ failure assessment (SOFA) score, organ failure, complications, interventions, bleeding time, bleeding site and outcome were compared between the two groups. Binary multivariate Logistic regression analysis was used to explore the risk factors of AH in SAP patients and whether the time and location of AH were risk factors affecting the outcome.Results:A total of 231 patients were enrolled in the analysis, including 198 patients without AH and 33 with AH (14.3%). There was no significant difference in gender, age or etiology between the two groups. The scores of APACHE Ⅱ and SOFA in AH group were significantly higher than those in non-AH group [APACHE Ⅱ score: 18 (12, 24) vs. 13 (9, 19), SOFA score: 9 (5, 15) vs. 5 (4, 11), both P < 0.01]. The incidences of acute kidney injury (AKI), gastrointestinal dysfunction, coagulation disorders, necrotic infection, pseudocyst and gastrointestinal fistula in AH group were significantly higher than those in non-AH group (66.7% vs. 47.0%, 36.4% vs. 7.1%, 18.2% vs. 6.6%, 66.7% vs. 9.1%, 66.7% vs. 34.3%, 9.1% vs. 1.5%, all P < 0.05). The proportions of requiring mechanical ventilation (MV) and surgical intervention in AH group were significantly higher than those in non-AH group (69.7% vs. 43.4, 48.5% vs. 14.6%, both P < 0.01). The length of intensive care unit (ICU) stay and hospital stay in AH group were significantly longer than those in non-AH group [length of ICU stay (days): 13 (8, 19) vs. 7 (3, 16), length of hospital stay: 24 (13, 40) vs. 17 (12, 24), both P < 0.01], and the hospital mortality was significantly higher (60.6% vs. 9.6%, P < 0.01). Multivariate Logistic regression analysis showed that APACHE Ⅱ score [odds ratio ( OR) = 1.157, 95% confidence interval (95% CI) was 1.030-1.299, P = 0.014], infectious necrosis ( OR = 12.211, 95% CI was 4.063-36.697, P < 0.01), pseudocyst ( OR = 3.568, 95% CI was 1.238-10.283, P = 0.019) and requiring MV ( OR = 0.089, 95% CI was 1.354-6.625, P = 0.007) were the risk factors of AH in SAP patients. In 33 AH patients, there was no significant difference in hospital mortality between early hemorrhage (occurred within 2 weeks of onset) and late hemorrhage (occurred 2 weeks after onset) groups [66.7% (8/12) vs. 57.1% (12/21), P > 0.05]. All 4 patients in the unspecified bleeding site group died during hospitalization; half or more patients died in the pseudocyst/abscess bleeding (14 cases), mesenteric/intestinal bleeding (13 cases) and gastric variceal bleeding (2 cases) groups (7 cases, 8 cases and 1 case respectively), and there were significant differences among the groups ( P < 0.05). Multivariate Logistic regression analysis showed that neither bleeding time ( OR = 0.989, 95% CI was 0.951-1.028, P = 0.574) nor bleeding site ( OR = 2.009, 95% CI was 0.822-4.907, P = 0.126) was the risk factor of death in patients with SAP combined with AH. Conclusions:Both early and late bleeding significantly increased the length of hospital stay and mortality of SAP patients. APACHE Ⅱ score, infectious necrosis and pseudocyst were the risk factors of AH in SAP patients. Neither bleeding time nor bleeding site was the risk factors of death in patients with SAP combined with AH. However, it still needed to be confirmed by a large sample clinical study.
10.An ultrapotent pan-β-coronavirus lineage B (β-CoV-B) neutralizing antibody locks the receptor-binding domain in closed conformation by targeting its conserved epitope.
Zezhong LIU ; Wei XU ; Zhenguo CHEN ; Wangjun FU ; Wuqiang ZHAN ; Yidan GAO ; Jie ZHOU ; Yunjiao ZHOU ; Jianbo WU ; Qian WANG ; Xiang ZHANG ; Aihua HAO ; Wei WU ; Qianqian ZHANG ; Yaming LI ; Kaiyue FAN ; Ruihong CHEN ; Qiaochu JIANG ; Christian T MAYER ; Till SCHOOFS ; Youhua XIE ; Shibo JIANG ; Yumei WEN ; Zhenghong YUAN ; Kang WANG ; Lu LU ; Lei SUN ; Qiao WANG
Protein & Cell 2022;13(9):655-675
New threats posed by the emerging circulating variants of SARS-CoV-2 highlight the need to find conserved neutralizing epitopes for therapeutic antibodies and efficient vaccine design. Here, we identified a receptor-binding domain (RBD)-binding antibody, XG014, which potently neutralizes β-coronavirus lineage B (β-CoV-B), including SARS-CoV-2, its circulating variants, SARS-CoV and bat SARSr-CoV WIV1. Interestingly, antibody family members competing with XG014 binding show reduced levels of cross-reactivity and induce antibody-dependent SARS-CoV-2 spike (S) protein-mediated cell-cell fusion, suggesting a unique mode of recognition by XG014. Structural analyses reveal that XG014 recognizes a conserved epitope outside the ACE2 binding site and completely locks RBD in the non-functional "down" conformation, while its family member XG005 directly competes with ACE2 binding and position the RBD "up". Single administration of XG014 is effective in protection against and therapy of SARS-CoV-2 infection in vivo. Our findings suggest the potential to develop XG014 as pan-β-CoV-B therapeutics and the importance of the XG014 conserved antigenic epitope for designing broadly protective vaccines against β-CoV-B and newly emerging SARS-CoV-2 variants of concern.
Angiotensin-Converting Enzyme 2
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Antibodies, Neutralizing
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Antibodies, Viral
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COVID-19
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Epitopes
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Humans
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SARS-CoV-2/genetics*
;
Spike Glycoprotein, Coronavirus/genetics*

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