2019新型冠状病毒S蛋白可能存在Furin蛋白酶切位点

2019年12月,中国武汉报道了2019新型冠状病毒(2019 novel Coronavirus,2019-nCoV)引起的肺炎。基于基因组信息,我们前期研究结果显示2019-nCoV与SARS冠状病毒虽然同属于Beta冠状病毒B亚群(BB冠状病毒),但两种病毒差异较大,这一结果与两者临床症状差异一致。前期研究还发现了BB冠状病毒存在大量的可变翻译,并从分子水平揭示了BB冠状病毒变异快、多样性高的特点。本研究在国际上首次报道Beta冠状病毒S蛋白上的一个重要突变,这个突变使2019-nCoV具有了一个可供Furin蛋白酶切的位点,是大部分Beta冠状病毒(特别是SARS和SARS样(SARS-like)冠状病毒)所不具有的。我们的一个结论是这个突变有可能增强了2019-nCoV侵染细胞的效率,进而使其传播力显著大于SARS冠状病毒。由于这个突变,2019-nCoV的感染机制也会不同于SARS等大部分Beta冠状病毒,而与鼠肝炎冠状病毒、HIV、埃博拉病毒和一些禽流感病毒的感染机制更相似。我们意外发现一些禽流感病毒也可以通过突变获得Furin蛋白酶切位点,这说明自然突变可以引入Furin酶切位点。除此之外,在2019-nCoV的S蛋白中插入的"CGGCGG"序列编码两个精氨酸,然而"CGG"对于宿主(人)来说是蛋白质翻译的稀有密码子。我们的另一个结论是引入Furin蛋白酶切位点的插入突变中包含的"CGGCGG"是传播到人之前形成的;2019-nCoV的中间宿主应该是密码子"CGG"相对使用频率更高的哺乳动物。使用我们提供的密码子"CGG"相对频率表结合2019-nCoV检测阳性的动物样品信息可以准确地确定2019-nCoV的中间宿主。对这个重要突变的后续研究将为揭示2019-nCoV传播力强的原因,以及为药物、抗体和疫苗的开发等工作奠定基础。     

5'非翻译区条形码揭示2019新型冠状病毒毒力

2019年12月,中国武汉报道了2019新型冠状病毒(2019 novel coronavirus,2019-nCoV)引起的肺炎。在前期研究中,我们在国际上首次报道了有关2019-nCoV的两个重要发现:①Beta冠状病毒B亚群存在大量的可变翻译;②2019-nCoV的S蛋白可能存在Furin蛋白酶切位点。本研究在国际上首次报道了2019-nCoV的5'非翻译区分析的结果:Beta冠状病毒可以根据其5'非翻译区条形码分为不同毒力的四个类;这四类对应Beta冠状病毒的四个亚群;已知的2019-nCoV与SARS冠状病毒的5'非翻译区条形码完全一样。作为本研究的最大贡献,我们在国际上首次提出5'非翻译区条形码可应用于病毒的检测、鉴定、分类以及进化研究。这种方法对于冠状病毒的预警和防控至关重要。本研究的最重要发现是内部核糖体进入位点很可能是影响冠状病毒毒力的重要因素。这个发现从分子水平揭示了2019-nCoV的毒力,并且为药物、抗体和疫苗的开发等应用提供直接指导。同时,我们提出一个基础理论方面的假说,起始密码子上游临近的茎环结构在真核生物的蛋白质翻译中起到重要作用。     

SARS冠状病毒在中国SARS流行中的分子进化

SARS最早出现在中国广东,紧接着SARS冠状病毒(SARS-Cov)被确定为致病原。找出SARS病毒基因组的变异与生物学之间的关系仍具有挑战性。最近,通过分子流行病学研究鉴别了传播中SARS-Cov的特征性变异序列。事实证明SARS-Cov是非人源的。     

SARS病毒与其他冠状病毒的基因组比较

本文利用生物信息学方法比较SARS病毒和其他冠状病毒基因组。通过数据库搜索,找出与SARS病毒基因组相似的核酸或蛋白质序列,并对相似序列进行比对,分析它们的共性和差异。结果表明,SARS病毒在基因组的组织上及结构蛋白质方面与现有冠状病毒有比较大的相似性,SARS病毒基因组与冠状病毒基因组相关。但是,SARS病毒基因组还存在一些特异性序列,ORF1a和S蛋白(特别是S1)的变化以及SARS—CoV特异性的非结构蛋白可能是SARS发病机理与传染特性区别于其他冠状病毒的分子基础。在全基因组水平上进行核酸单词出现频率分析,结果表明,SARS病毒远离已知的其他冠状病毒,单独成为一类。     

SARS病毒与其他冠状病毒的基因组比较

本文利用生物信息学方法比较SARS病毒和其他冠状病毒基因组.通过数据库搜索,找出与SARS病毒基因组相似的核酸或蛋白质序列,并对相似序列进行比对,分析它们的共性和差异.结果表明,SARS病毒在基因组的组织上及结构蛋白质方面与现有冠状病毒有比较大的相似性,SARS病毒基因组与冠状病毒基因组相关.但是,SARS病毒基因组还存在一些特异性序列,ORF1a和S蛋白(特别是S1)的变化以及SARS-CoV特异性的非结构蛋白可能是SARS发病机理与传染特性区别于其他冠状病毒的分子基础.在全基因组水平上进行核酸单词出现频率分析,结果表明,SARS病毒远离已知的其他冠状病毒,单独成为一类.     

SARS冠状病毒PLpro蛋白酶的结构与功能

SARS冠状病毒基因组编码2种病毒蛋白酶,即木瓜样蛋白酶（PLpro）和3C样蛋白酶(3CLpro).其中,PLpro蛋白酶结构与功能研究是近年来冠状病毒分子生物学研究的热点之一. PLpro蛋白酶参与SARS冠状病毒1a(1ab)复制酶多聚蛋白N端部分的切割加工,是SARS冠状病毒复制酶复合体(RC)形成的重要调节蛋白分子;最新研究表明,SARS冠状病毒PLpro蛋白酶是一种病毒编码的去泛素化酶（DUB）,对细胞蛋白具有明显去泛素化作用;而且对泛素(Ub)和泛素样分子ISG15均具有活性. PLpro蛋白酶对宿主抗病毒天然免疫反应具有负调节作用,是SARS冠状病毒的一种重要干扰素拮抗分子.PLpro蛋白酶是一种多功能病毒蛋白酶.本文结合作者课题组研究工作,对SARS冠状病毒PLpro蛋白酶结构和功能研究最新进展进行综述.     

2019新型冠状病毒信息库

2019年12月在中国武汉开始爆发的新型肺炎已造成全球25个国家/地区的31516人感染、638人死亡(截止2020年2月7日16时),引起该肺炎的病毒被世界卫生组织命名为2019新型冠状病毒(2019-nCoV)。为促进2019-nCoV数据共享应用并及时向全球公众提供病毒的相关信息,国家生物信息中心(CNCB)/国家基因组科学数据中心(NGDC)建立了2019新型冠状病毒信息库(2019nCoVR,https://bigd.big.ac.cn/ncov)。该信息库整合了来自德国全球流感病毒数据库、美国国家生物技术信息中心、深圳(国家)基因库、国家微生物科学数据中心及CNCB/NGDC等机构公开发布的2019-nCoV核苷酸和蛋白质序列数据、元信息、学术文献、新闻动态、科普文章等信息,开展了不同冠状病毒株的基因组序列变异分析并提供可视化展示。同时,2019nCoVR无缝对接CNCB/NGDC的相关数据库,提供新测序病毒株系的基因组原始测序数据、组装后序列的在线汇交、管理与共享、国际数据库同步发布等数据服务。本文对2019nCoVR数据汇交、管理、发布及使用等进行全面阐述,以方便用户了解该信息库各项功能及数据状况,为加速开展病毒的分类溯源、变异演化、快速检测、药物研发以及新型肺炎的精准预防与治疗等研究提供重要基础。     

冠状病毒的新成员--SARS-CoV的基因组特性

2003年3月,人类发现一种新的冠状病毒SARS-CoV,这种病毒是非典型性肺炎(SARS)的病原体。SARS-CoV的基因组序列已经由包括中国科学家在内的全世界的科研人员测定完成。该文对国际报道的SARS病源的基因序列进行了收录,阐述了SARS-CoV基因组的基本特性：SARS-CoV的基因组长约28-30kb,与冠状病毒科的基因组长度相符合,其中包括11个编码序列,基因组的组织方式也与其他冠状病毒类似,从表面蛋白(S蛋白)、外膜蛋白(M蛋白)和核蛋白(N蛋白)上看,SARS病毒与其他冠状病毒的对应蛋白进化关系接近。同时发现,在某些区域,SARS病毒的基因序列与其他冠状病毒存在相当大的差异,具有自身比较保守的基因组序列结构。而且氨基酸的序列也与其他冠状病毒有很大程度的不同。基因信息的冗余分析表明,SARS-CoV具有较低的冗余度,即发生变异的可能性比较大。虽然SARS-CoV外表与冠状病毒类似,亲缘关系未超出冠状病毒科界限,但由于蛋白基因与氨基酸的序列与其他冠状病毒有本质不同,因此可能不是其他冠状病毒的变异体,而是一种与冠状病毒类似、但早已独立存在、此前未被人类所认识的新病毒。     

SARS病原体特征与临床实验室诊断

SARS的全球性流行带来了严重的公共卫生问题和社会经济问题。目前,在SARS病原体鉴定、基因组结构和序列变异、SARS流行特征和实验室诊断等方面获得了很大的进展。现已证实SARS的病原体为SARS冠状病毒。SARS冠状病毒是一种与原来已知冠状病毒在某些方面类似、但又独具特征的新型冠状病毒,该病毒的起源可能源于野生动物。多个SARS冠状病毒的全基因组核酸序列测定现已完成,在SARS冠状病毒的实验室诊断方面,现已有了免疫学方法检查抗体和分子生物学方法检查病毒RNA。直接检测病毒抗原和定量检测病毒多靶点基因是今后的发展方向。     

安徽省境外输入新冠病毒Delta变异株的首次发现与鉴定

为鉴定此次安徽省境外输入新型冠状病毒的分子特征,本研究对两例病例进行了高通量测序和基因组序列分析。高通量测序获得两株病毒的基因组全长分别为29 858nt和29 858nt,利用NextStrain和2019新型冠状病毒信息库（https：//ngdc.cncb.ac.cn/ncov/）在线分析对两例毒株全基因组核苷酸和氨基酸变异位点进行分析。将全基因组序列上传到（https：//pangolin.cog-uk.io）和（https：//clades.nextstrain.org/）网站,通过在线网站分析结果显示,两株病毒均为B.1.617.2变异株（Delta）,NextStrain进化分析为21A。两株毒株分别发现了49和48个核苷酸突变位点,氨基酸的变异位点分别有35和34个,其中存在相同的7个同义突变。两株病毒主要在ORF7a基因上C27527T(P45L)的突变不同。这是安徽省首次发现境外输入的B.1.617.2变异株（Delta株）此变异株存在引发本地的流行和爆发的风险,需要严密持续的对境外输入病例进行流行病学调查和病毒基因分子特征分析。     

Pathogenicity and transmissibility of 2019-nCoV—A quick overview and comparison with other emerging viruses

A zoonotic coronavirus, tentatively labeled as 2019-nCoV by the World Health Organization (WHO), has been identified as the causative agent of the viral pneumonia outbreak in Wuhan, China, at the end of 2019. Although 2019-nCoV can cause a severe respiratory illness like SARS and MERS, evidence from clinics suggested that 2019-nCoV is generally less pathogenic than SARS-CoV, and much less than MERS-CoV. The transmissibility of 2019-nCoV is still debated and needs to be further assessed. To avoid the 2019-nCoV outbreak turning into an epidemic or even a pandemic and to minimize the mortality rate, China activated emergency response procedures, but much remains to be learned about the features of the virus to refine the risk assessment and response. Here, the current knowledge in 2019-nCoV pathogenicity and transmissibility is summarized in comparison with several commonly known emerging viruses, and information urgently needed for a better control of the disease is highlighted.     

Inefficiency of Sera from Mice Treated with Pseudotyped SARS-CoV to Neutralize 2019-nCoV Infection

The novel coronavirus 2019-nCoV has caused the pandemic of Wuhan pneumonia recently, posing a serious threat to global public health, and thus calling for the development of therapeutics and prophylactics. Here we showed that high titer anti-SARS-CoV spike protein serum cannot effectively neutralize 2019-nCoV infection. Based on our previous research, we developed SARS pseudovirus (SARS-PsV) and MERS pseudovirus (MERS-PsV) as immunogens to immunize mice. We found sera from mice treated with SARS-CoV S protein could potently cross-neutralize infection by SARS-CoV (50% neutralizing antibody titers, NT50 > 40, 000) and SARS-related coronavirus (NT50 > 7, 000), but weakly for 2019-nCoV infection NT50 < 100), implying that it may not be practical to treat 2019-nCoV infection with anti-SARS-CoV antibodies and that people with history of SARS-CoV infection many years ago may not be resistant to 2019-nCoV infection.     

The epidemic of 2019-novel-coronavirus (2019-nCoV) pneumonia and insights for emerging infectious diseases in the future

At the end of December 2019, a novel coronavirus, 2019-nCoV, caused an outbreak of pneumonia spreading from Wuhan, Hubei province, to the whole country of China, which has posed great threats to public health and attracted enormous attention around the world. To date, there are no clinically approved vaccines or antiviral drugs available for these human coronavirus infections. Intensive research on the novel emerging human infectious coronaviruses is urgently needed to elucidate their route of transmission and pathogenic mechanisms, and to identify potential drug targets, which would promote the development of effective preventive and therapeutic countermeasures. Herein, we describe the epidemic and etiological characteristics of 2019-nCoV, discuss its essential biological features, including tropism and receptor usage, summarize approaches for disease prevention and treatment, and speculate on the transmission route of 2019-nCoV.     

新型冠状病毒上海株(nCoV-SH01)的分离和鉴定

新型冠状病毒肺炎(coronavirus disease 2019,COVID-19)疫情对人类生命健康构成极大威胁。病毒的分离是构建新型冠状病毒(2019 novel coronavirus, 2019-nCoV)细胞感染模型和动物感染模型的基础。本研究利用冠状病毒易感的Vero E6细胞,从1例上海感染者的咽拭子中分离到一株2019-nCoV,命名为nCoV-SH01。对该毒株全基因组采用一代Sanger和二代Illumina法测序,发现该毒株与GenBank MN908947的同源性＞99.99%。免疫荧光检测显示,该毒株与COVID-19康复者的血清呈阳性反应。当nCoV-SH01感染Vero E6细胞后,导致典型的合胞体病变,细胞病变效应明显且进展迅速,提示nCoV-SH01可用于进一步建立2019-nCoV的细胞感染和动物感染模型,为开展致病性研究以及抗病毒药物和疫苗研发奠定了基础。     

Vaccine development and therapeutic design for 2019-nCoV/SARS-CoV-2: Challenges and chances

The ongoing outbreak of the recently emerged 2019 novel coronavirus (nCoV), which has seriously threatened global health security, is caused by severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) with high morbidity and mortality. Despite the burden of the disease worldwide, still, no licensed vaccine or any specific drug against 2019-nCoV is available. Data from several countries show that few repurposed drugs using existing antiviral drugs have not (so far) been satisfactory and more recently were proven to be even highly toxic. These findings underline an urgent need for preventative and therapeutic interventions designed to target specific aspects of 2019-nCoV. Again the major factor in this urgency is that the process of data acquisition by physical experiment is time-consuming and expensive to obtain. Scientific simulations and more in-depth data analysis permit to validate or refute drug repurposing opportunities predicted via target similarity profiling to speed up the development of a new more effective anti-2019-nCoV therapy especially where in vitro and/or in vivo data are not yet available. In addition, several research programs are being developed, aiming at the exploration of vaccines to prevent and treat the 2019-nCoV. Computational-based technology has given us the tools to explore and identify potentially effective drug and/or vaccine candidates which can effectively shorten the time and reduce the operating cost. The aim of the present review is to address the available information on molecular determinants in disease pathobiology modules and define the computational approaches employed in systematic drug repositioning and vaccine development settings for SARS-CoV-2.     

Measures for diagnosing and treating infections by a novel coronavirus responsible for a pneumonia outbreak originating in Wuhan,China

On 10 January 2020, a new coronavirus causing a pneumonia outbreak in Wuhan City in central China was denoted as 2019-nCoV by the World Health Organization (WHO). As of 24 January 2020, there were 887 confirmed cases of 2019-nCoV infection, including 26 deaths, reported in China and other countries. Therefore, combating this new virus and stopping the epidemic is a matter of urgency. Here, we focus on advances in research and development of fast diagnosis methods, as well as potential prophylactics and therapeutics to prevent or treat 2019-nCoV infection.     

Prevalence and genetic diversity of coronaviruses in bats from China

Coronaviruses can infect a variety of animals including poultry, livestock, and humans and are currently classified into three groups. The interspecies transmissions of coronaviruses between different hosts form a complex ecosystem of which little is known. The outbreak of severe acute respiratory syndrome (SARS) and the recent identification of new coronaviruses have highlighted the necessity for further investigation of coronavirus ecology, in particular the role of bats and other wild animals. In this study, we sampled bat populations in 15 provinces of China and reveal that approximately 6.5% of the bats, from diverse species distributed throughout the region, harbor coronaviruses. Full genomes of four coronavirues from bats were sequenced and analyzed. Phylogenetic analyses of the spike, envelope, membrane, and nucleoprotein structural proteins and the two conserved replicase domains, putative RNA-dependent RNA polymerase and RNA helicase, revealed that bat coronaviruses cluster in three different groups: group 1, another group that includes all SARS and SARS-like coronaviruses (putative group 4), and an independent bat coronavirus group (putative group 5). Further genetic analyses showed that different species of bats maintain coronaviruses from different groups and that a single bat species from different geographic locations supports similar coronaviruses. Thus, the findings of this study suggest that bats may play an integral role in the ecology and evolution of coronaviruses.     

Evaluation of affymetrix severe acute respiratory syndrome resequencing GeneChips in characterization of the genomes of two strains of coronavirus infecting humans

Severe acute respiratory syndrome (SARS) was discovered during a recent global outbreak of atypical pneumonia. A number of immunologic and molecular studies of the clinical samples led to the conclusion that a novel coronavirus (SARS-CoV) was associated with the outbreak. Later, a SARS resequencing GeneChip was developed by Affymetrix to characterize the complete genome of SARS-CoV on a single GeneChip. The present study was carried out to evaluate the performance of SARS resequencing GeneChips. Two human SARS-CoV strains (CDC#200301157 and Urbani) were resequenced by the SARS GeneChips. Five overlapping PCR amplicons were generated for each strain and hybridized with these GeneChips. The successfully hybridized GeneChips generated nucleotide sequences of nearly complete genomes for the two SARS-CoV strains with an average call rate of 94.6%. Multiple alignments of nucleotide sequences obtained from SARS GeneChips and conventional sequencing revealed full concordance. Furthermore, the GeneChip-based analysis revealed no additional polymorphic sites. The results of this study suggest that GeneChip-based genome characterization is fast and reproducible. Thus, SARS resequencing GeneChips may be employed as an alternate tool to obtain genome sequences of SARS-CoV strains pathogenic for humans in order to further understand the transmission dynamics of these viruses.     

新型冠状病毒的动物源性和传染源控制

根据现有的数据,新型冠状病毒(2019 novel coronavirus,2019-nCoV)比严重急性呼吸综合征冠状病毒(severe acute respiratory syndrome coronavirus,SARS-CoV)的传染性强、传播速度快、疫情规模大、病死率低。其传染性、传播速度和疫情规模似乎具有甲型流感病毒(influenza A virus)的特点。尽管2019-nCoV来源于何种动物尚无定论,但它与SARS-CoV同属冠状病毒,具有共同之处。如果流行过后 2019-nCoV没能在人群中持续传播和存在(如同SARS-CoV一样),则控制野生动物传染源乃重中之重;如果2019-nCoV获得了能在人群中持续传播的能力,预防控制策略将与SARS-CoV明显不同,疫苗便成为至关重要的手段。