Identification of Human Single-Domain Antibodies against SARS-CoV-2

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Engineered Ultra-High Affinity Synthetic Antibodies for SARS-CoV-2 Neutralization and Detection

The Covid-19 pandemic is a centenarial global catastrophe. Similar events are likely to be recurring with more frequency in the future. The inability to control the virus’ impact is caused by many factors, but the lack of a technology infrastructure to detect and impede the virus at an early stage are principal shortcomings. Using phage display mutagenesis, we have generated a cohort of high performance antibody fragments (Fabs) that can be used in a sensitive point of care (POC) assay and are potent inhibitors (IC₅₀-0.5 nM) to viral entry into cells. The POC assay is based on a split-enzyme (β-lactamase) complementation strategy that detects virus particles at low nM levels. We have shown that this assay is equally effective for detecting other viruses like Ebola and Zika. Importantly, its components can be freeze dried and stored, but becomes fully active when rehydrated.     

GICA和CLIA联合检测SARS-CoV-2特异性抗体的检测策略研究

评价胶体金免疫层析法(GICA)与化学发光法(CLIA)联合检测对降低新型冠状病毒(SARS-CoV-2)特异性抗体假阳性的效果。收集2020年1月22日至2020年3月5日就诊于川北医学院附属医院及南充市中心医院的19例SARS-CoV-2确诊患者不同时段的血清33份,55例非SARS-CoV-2、其他病原体感染及自身免疫性疾病患者的血清55份,采用GICA和CLIA分别对血清SARS-CoV-2 IgM、IgG进行检测,并对结果进行分析。GCIA检测SARS-CoV-2 IgM、IgG的敏感性分别为100.0%、94.74%,与CLIA(92.86%和100.0%)比较没有差异(P>0.05);GCIA检测SARS-CoV-2 IgM、IgG的特异性分别为70.91%、74.55%,明显低于CLIA的特异性(98.18%和89.09%)(P<0.01);两种方法检测SARS-CoV-2 IgM、IgG结果具有一致性(P<0.001),Kappa值分别为0.434,0.406;ROC曲线分析发现,GCIA检测SARS-CoV-2 IgM、IgG的AUC分别为0.855、0.846,明显低于CLIA(0.955和0.945)(P<0.05)。两种方法联合检测SARS-CoV-2 IgM、IgG的敏感性分别为92.86%、94.74%,特异性分别为100.0%、100.0%;ROC曲线分析显示,联合检测SARS-CoV-2 IgM、IgG的AUC分别为0.964、0.974,高于两种方法的单独检测。GICA和CLIA联合检测能有效提高SARS-CoV-2 IgM和IgG的检测特异性,值得临床推广应用。     

Antibodies to lipids and liposomes: immunology and safety

Naturally occurring antibodies to phospholipids and cholesterol are widespread; they occur commonly during the course of acute infections; they are not causally related to the anti-phospholipid syndrome; they have been associated with other clinical entities only as an epiphenomenon; and they have not been implicated as causing any clinical syndrome or disease. There are theoretical and experimental reasons to believe that normal cells and tissues are protected from binding of antibodies to bilayer lipids by steric hindrance due to adjacent larger molecules, such as large or charged adjacent glycolipids or proteins on the cell surface. There are also reasons to believe that certain natural antibodies to lipids can even serve useful normal functions. Antibodies to liposomal lipids induced by liposomes containing lipid A appear to have characteristics that are similar or identical to naturally occurring antibodies to lipids, and it is therefore believed that such antibodies would not cause adverse clinical effects. Numerous Phase I and II human clinical trials of experimental vaccines containing liposomes and lipid A have shown a high level of safety.     

Tetravalent SARS-CoV-2 Neutralizing Antibodies Show Enhanced Potency and Resistance to Escape Mutations

Neutralizing antibodies (nAbs) hold promise as therapeutics against COVID-19. Here, we describe protein engineering and modular design principles that have led to the development of synthetic bivalent and tetravalent nAbs against SARS-CoV-2. The best nAb targets the host receptor binding site of the viral S-protein and tetravalent versions block entry with a potency exceeding bivalent nAbs by an order of magnitude. Structural studies show that both the bivalent and tetravalent nAbs can make multivalent interactions with a single S-protein trimer, consistent with the avidity and potency of these molecules. Significantly, we show that the tetravalent nAbs show increased tolerance to potential virus escape mutants and an emerging variant of concern. Bivalent and tetravalent nAbs can be produced at large-scale and are as stable and specific as approved antibody drugs. Our results provide a general framework for enhancing antiviral therapies against COVID-19 and related viral threats, and our strategy can be applied to virtually any antibody drug.     

新型冠状病毒RBD蛋白原核表达及多克隆抗体的制备

为原核表达严重急性呼吸综合征冠状病毒2（简称新型冠状病毒,severe acute respiratory syndrome-coronavirus 2,SARS-CoV-2）S蛋白受体结合域（receptor binding domain, RBD）并制备多克隆抗体,利用基因克隆技术将RBD基因连接到原核表达载体pGEX-6p-1和pET-32a(+)上,电转化至大肠杆菌XL1-Blue感受态细胞,利用优化后的表达条件大量表达重组蛋白,经亲和层析纯化后通过SDS-PAGE检测蛋白的表达情况。利用GST-RBD融合蛋白作为免疫抗原免疫小鼠制备多克隆抗体,ELISA和Western blot分析抗血清的效价和特异性。PCR鉴定和序列测定结果显示,成功构建了重组载体pGEX-RBD和pET-RBD,在大肠杆菌中实现了GST-RBD和RBD-His融合蛋白的可溶性高效表达。研究获得的多克隆抗体的滴度达到约1∶3 000,并具有良好的结合特异性。原核表达的可溶性新型冠状病毒RBD重组蛋白具有良好的免疫原性,为后续制备基因工程抗体奠定了实验基础。     

Dynamic Changes of Antibodies to SARS-CoV-2 in COVID-19 Patients at Early Stage of Outbreak

Virologica Sinica - The coronavirus disease 2019 (COVID-19), caused by SARS-CoV-2, has spread around the world with high mortality. To diagnose promptly and accurately is the vital step to...     

新型冠状病毒的糖基化、糖受体识别及糖链抑制剂的发现北大核心CSCD

新型冠状病毒疫情(COVID-19)是21世纪截至目前人类面对的最为严重的公共卫生事件。疫苗、中和抗体以及小分子化合药物的出现有效预防和阻止了COVID-19的快速传播,而不断出现的病毒突变体却使这些疫苗及药物的效价降低,这对COVID-19的预防及治疗提出了新的挑战。新型冠状病毒(SARS-CoV-2)通常会先黏附于呼吸道表面的大分子糖链——硫酸乙酰肝素,进而与特异性受体人血管紧张素转化酶2(human angiotensin-converting enzyme 2,hACE2)结合,从而实现对人体的侵入。SARS-CoV-2的刺突(spike,S)蛋白是高度糖基化的,而糖基化对于hACE2与S蛋白的结合也有着重要影响,S蛋白在宿主体内还会被一系列凝集素受体所结合,这意味着糖链在SARS-CoV-2的入侵及感染过程中有着重要的作用。基于SARS-CoV-2的糖基化及糖受体识别机制开发糖链抑制剂可能是预防或治疗新型冠状病毒感染的有效手段,相关研究发现海洋来源的硫酸化多糖、肝素分子及其他的一些糖类具有抗SARS-CoV-2的活性。本文系统阐述了新型冠状病毒的糖基化及其糖链在入侵、感染中的作用,并对抗SARS-CoV-2糖链抑制剂的发现和机制研究现状进行了总结,在此基础上还对糖类抗病毒药物的机遇与挑战进行了展望。     

Correction to: Dynamic Changes of Antibodies to SARS-CoV-2 in COVID-19 Patients at Early Stage of Outbreak

Virologica Sinica - Due to type-setting error, the affiliation of author Huaqing Shu and Shuzhen Wang was mislabeled.     

Antibodies to the N-Terminal Domain of Angiotensin-Converting Enzyme (ACE2) That Block Its Interaction with SARS-CoV-2 S Protein

Doklady Biochemistry and Biophysics - SARS-CoV-2 is a new coronavirus that is the cause of COVID-19 pandemic. To enter the cell, the virus interacts via its surface S protein with...     

Principles of SARS-CoV-2 glycosylation

The structure and post-translational processing of the SARS-CoV-2 spike glycoprotein (S) is intimately associated with the function of the virus and of sterilising vaccines. The surface of the S protein is extensively modified by glycans, and their biosynthesis is driven by both the wider cellular context, and importantly, the underlining protein structure and local glycan density. Comparison of virally derived S protein with both recombinantly derived and adenovirally induced proteins, reveal hotspots of protein-directed glycosylation that drive conserved glycosylation motifs. Molecular dynamics simulations revealed that, while the S surface is extensively shielded by N-glycans, it presents regions vulnerable to neutralising antibodies. Furthermore, glycans have been shown to influence the accessibility of the receptor binding domain and the binding to the cellular receptor. The emerging picture is one of unifying, principles of S protein glycosylation and an intimate role of glycosylation in immunogen structure and efficacy.