Expression cloning of functional receptor used by SARS coronavirus

We have expressed a series of truncated spike (S) glycoproteins of SARS-CoV and found that the N-terminus 14-502 residuals were sufficient to bind to SARS-CoV susceptible Vero E6 cells. With this soluble S protein fragment as an affinity ligand, we screened HeLa cells transduced with retroviral cDNA library from Vero E6 cells and obtained a HeLa cell clone which could bind with the S protein. This cell clone was susceptible to HIV/SARS pseudovirus infection and the presence of a functional receptor for S protein in this cell clone was confirmed by the cell-cell fusion assay. Further studies showed the susceptibility of this cell was due to the expression of endogenous angiotensin-converting enzyme 2 (ACE2) which was activated by inserted LTR from retroviral vector used for expression cloning. When human ACE2 cDNA was transduced into NIH3T3 cells, the ACE2 expressing NIH3T3 cells could be infected with HIV/SARS pseudovirus. These data clearly demonstrated that ACE2 was the functional receptor for SARS-CoV.     

Characterization of SARS-CoV main protease and identification of biologically active small molecule inhibitors using a continuous fluorescence-based assay

Severe acute respiratory syndrome associated coronavirus main protease (SARS-CoV Mpro) has been proposed as a prime target for anti-SARS drug development. We have cloned and overexpressed the SARS-CoV Mpro in Escherichia coli, and purified the recombinant Mpro to homogeneity. The kinetic parameters of the recombinant SARS-CoV Mpro were characterized by high performance liquid chromatography-based assay and continuous fluorescence-based assay. Two novel small molecule inhibitors of the SARS-CoV Mpro were identified by high-throughput screening using an internally quenched fluorogenic substrate. The identified inhibitors have Ki values at low microM range with comparable anti-SARS-CoV activity in cell-based assays.     

针对leader序列的siRNA能够有效抑制SARS冠状病毒多个mRNA的表达

小干扰RNAs(siRNAs)能够有效降解具有互补序列的RNA.在SARS-CoV的基因组RNA和所有亚基因组RNA的5′端均有一段共同的leader序列,而且该leader序列在不同的病毒分离物中高度保守,因此leader序列可作为一个用于抑制SARS-CoV复制的有效靶点.研究表明,针对leader序列化学合成的siRNA和DNA载体表达的shRNA都可以有效抑制SARS-CoV mRNA的表达.Leader序列特异的siRNA或shRNA不仅可以有效抑制leader与报告基因EGFP融合基因的表达,而且还可以有效抑制leader与刺突蛋白(spikeprotein)、膜蛋白(membrane protein)和核衣壳蛋白(nucleocapsid protein)基因的融合转录产物的表达.结果表明,针对leader序列的RNA干扰可以发展成为一种抗SARS-CoV治疗的有效策略.     

Cleavage of spike protein of SARS coronavirus by protease factor Xa is associated with viral infectivity

The spike (S) protein of SARS coronavirus (SARS-CoV) has been known to recognize and bind to host receptors, whose conformational changes then facilitate fusion between the viral envelope and host cell membrane, leading to viral entry into target cells. However, other functions of SARS-CoV S protein such as proteolytic cleavage and its implications to viral infection are incompletely understood. In this study, we demonstrated that the infection of SARS-CoV and a pseudovirus bearing the S protein of SARS-CoV was inhibited by a protease inhibitor Ben-HCl. Also, the protease Factor Xa, a target of Ben-HCl abundantly expressed in infected cells, was able to cleave the recombinant and pseudoviral S protein into S1 and S2 subunits, and the cleavage was inhibited by Ben-HCl. Furthermore, this cleavage correlated with the infectivity of the pseudovirus. Taken together, our study suggests a plausible mechanism by which SARS-CoV cleaves its S protein to facilitate viral infection.     

SARS冠状病毒的分离培养与鉴定

采集急性期病人的咽拭子或漱口液,用Vero、Vero E6、MDCK、Hela、Hep-2等传代细胞,人胚肺二倍体细胞(HEL)和人胚肺(HP)细胞分离培养严重急性呼吸系统综合症(SARS)的病原体。结果用Vero、Vero E6、MDCK和HP细胞从标本中分离到一株病毒。间接免疫荧光试验发现,恢复期病人血清可与所分离的病毒起反应,在胞膜和胞浆中出现翠绿色荧光;中和试验结果表明,恢复期病人血清能中和病毒对细胞的致细胞病变作用;电镜下可观察到冠状病毒样颗粒;RT-PCR法可扩增到冠状病毒特异性基因片段,且其核苷酸序列与国内外发表的SARS冠状病毒(SARS-Cov)相应的基因序列相符,同源性达到100％。从传染性非典型肺炎病人的漱口液中分离到SARS冠状病毒,这种病毒与传染性非典型肺炎密切相关。     

SARS冠状病毒主蛋白酶抑制剂的筛选及抑制动力学研究

对SARS冠状病毒主蛋白酶(SARS-CoV M^pro)进行异源重组表达与提纯,并以其为靶点,利用基于荧光共振能量转移(FRET)技术的体外药物筛选模型,对蛋白酶抑制剂聚焦库96种化合物进行了体外抑制活性的评价,并从动力学的角度探讨筛选出的阳性化合物对SARS-CoV M^pro的抑制能力与机制。结果表明:通过筛选获得抑制率>80%、淬灭率<20%的化合物5种,为P-1-08、P-1-19、P-2-24、P-2-28、P-2-54,其半数有效抑制浓度(IC₅₀)分别为:0.69±0.05μmol/L、1.19±0.41μmol/L、0.14±0.01μmol/L、1.36±0.07μmol/L、0.36±0.03μmol/L。其中化合物P-1-08、P-1-19、P-2-24、P-2-54对SARS冠状病毒主蛋白酶的抑制作用为不可逆抑制,化合物P-2-28的抑制作用为可逆抑制。根据Lineweaver-Burk图和Dixon图的研究,发现化合物P-2-28对SARS冠状病毒主蛋白酶呈竞争性抑制,抑制常数Ki为0.81μmol/L。通过对底物浓度,IC₅₀值及Ki值关系的研究,进一步验证了P-2-28的抑制作用为竞争性抑制。该抑制剂的发现为SARS冠状病毒主蛋白酶抑制剂的研究打下基础,为抗SARS病毒药物开发提供了先导化合物。     

Immunogenicity of the spike glycoprotein of Bat SARS-like coronavirus

A group of SARS-like coronaviruses(SL-CoV)have been identified in horseshoe bats.Despite SL-CoVs and SARS-CoV share identical genome structure and high-level sequence similarity,SL-CoV does not bind to the same cellular receptor as for SARS-CoV and the N-terminus of the S proteins only share 64%amino acid identity,suggesting there are fundamental differences between these two groups of coronaviruses.To gain insight into the basis of this difference,we established a recombinant adenovirus system expressing the S protein from SL-CoV(rAd-Rp3-S)to investigate its immune characterization.Our results showed that immunized mice generated strong humoral immune responses against the SL-CoV S protein.Moreover,a strong cellular immune response demonstrated by elevated IFN-γand IL-6 levels was also observed in these mice.However,the induced antibody from these mice had weaker cross-reaction with the SARS-CoV S protein,and did not neutralize HIV pseudotyped with SARS-CoV S protein.These results demonstrated that the immunogenicity of the SL-CoV S protein is distinct from that of SARS-CoV,which may cause the immunological differences between human SARS-CoV and bat SL-CoV.Furthermore,the recombinant virus could serve as a potential vaccine candidate against bat SL-CoV infection.     

Liberation of SARS-CoV main protease from the viral polyprotein: N-terminal autocleavage does not depend on the mature dimerization mode

The main protease (M^pro) plays a vital role in proteolytic processing of the polyproteins in the replicative cycle of SARS coronavirus (SARS-CoV). Dimerization of this enzyme has been shown to be indispensable for trans-cleavage activity. However, the auto-processing mechanism of M^pro, i.e. its own release from the polyproteins through autocleavage, remains unclear. This study elucidates the relationship between the N-terminal autocleavage activity and the dimerization of “immature” M^pro. Three residues (Arg4, Glu290, and Arg298), which contribute to the active dimer conformation of mature M^pro, are selected for mutational analyses. Surprisingly, all three mutants still perform N-terminal autocleavage, while the dimerization of mature protease and trans-cleavage activity following auto-processing are completely inhibited by the E290R and R298E mutations and partially so by the R4E mutation. Furthermore, the mature E290R mutant can resume N-terminal autocleavage activity when mixed with the “immature” C145A/E290R double mutant whereas its trans-cleavage activity remains absent. Therefore, the N-terminal auto-processing of M^pro appears to require only two “immature” monomers approaching one another to form an “intermediate” dimer structure and does not strictly depend on the active dimer conformation existing in mature protease. In conclusion, an auto-release model of M^pro from the polyproteins is proposed, which will help understand the auto-processing mechanism and the difference between the autocleavage and trans-cleavage proteolytic activities of SARS-CoV M^pro.     

Three-dimensional domain swapping as a mechanism to lock the active conformation in a super-active octamer of SARS-CoV main protease

Proteolytic processing of viral polyproteins is indispensible for the lifecycle of coronaviruses. The main protease (M^pro) of SARS-CoV is an attractive target for anti-SARS drug development as it is essential for the polyprotein processing. M^pro is initially produced as part of viral polyproteins and it is matured by autocleavage. Here, we report that, with the addition of an N-terminal extension peptide, M^pro can form a domain-swapped dimer. After complete removal of the extension peptide from the dimer, the mature M^pro self-assembles into a novel super-active octamer (AO-M^pro). The crystal structure of AO-M^pro adopts a novel fold with four domain-swapped dimers packing into four active units with nearly identical conformation to that of the previously reported M^pro active dimer, and 3D domain swapping serves as a mechanism to lock the active conformation due to entanglement of polypeptide chains. Compared with the previously well characterized form of M^pro, in equilibrium between inactive monomer and active dimer, the stable AO-M^pro exhibits much higher proteolytic activity at low concentration. As all eight active sites are bound with inhibitors, the polyvalent nature of the interaction between AO-M^pro and its polyprotein substrates with multiple cleavage sites, would make AO-M^pro functionally much more superior than the M^pro active dimer for polyprotein processing. Thus, during the initial period of SARS-CoV infection, this novel active form AO-M^pro should play a major role in cleaving polyproteins as the protein level is extremely low. The discovery of AO-M^pro provides new insights about the functional mechanism of M^pro and its maturation process.