SARS病毒核蛋白基因的克隆及其表达研究

从一例输入性传染性非典型性肺炎病人血清中提取病毒RNA,通过RT—PCR方法扩增出SARS病毒核蛋白基因片段,克隆入质粒载体pUCm—T后,进行核苷酸序列的测定及分析,与已公布的SARS病毒基因序列进行比较,证实为SARS冠状病毒核蛋白基因。为了解该病毒核蛋白的抗原特性,将核蛋白基因插入表达载体,构建重组质粒pET28a—SN,转导大肠杆菌BL21(DE3)后,加IPTG诱导表达。产物经SDS—PAGE电泳分析,表达出相对分子量约为50kDa的蛋白,占整个菌体的45％左右。Westem—blot分析表明,表达产物仅与SARS阳性病人血清起反应,而与正常血清不起反应。间接ELISA免疫检测,抗原滴度达1：12500。表明表达的核蛋白为SARS特异性抗原,这为SARS病毒的诊断试剂的研制提供了方便而安全的抗原来源。     

Using models to identify routes of nosocomial infection: a large hospital outbreak of SARS in Hong Kong

Two factors dominated the epidemiology of severe acute respiratory syndrome (SARS) during the 2002-2003 global outbreak, namely super-spreading events (SSE) and hospital infections. Although both factors were important during the first and the largest hospital outbreak in Hong Kong, the relative importance of different routes of infection has not yet been quantified. We estimated the parameters of a novel mathematical model of hospital infection using SARS episode data. These estimates described levels of transmission between the index super-spreader, staff and patients, and were used to compare three plausible hypotheses. The broadest of the supported hypotheses ascribes the initial surge in cases to a single super-spreading individual and suggests that the per capita risk of infection to patients increased approximately one month after the start of the outbreak. Our estimate for the number of cases caused by the SSE is substantially lower than the previously reported values, which were mostly based on self-reported exposure information. This discrepancy suggests that the early identification of the index case as a super-spreader might have led to biased contact tracing, resulting in too few cases being attributed to staff-to-staff transmission. We propose that in future outbreaks of SARS or other directly transmissible respiratory pathogens, simple mathematical models could be used to validate preliminary conclusions concerning the relative importance of different routes of transmission with important implications for infection control.     

Inference of functional properties from large-scale analysis of enzyme superfamilies

As increasingly large amounts of data from genome and other sequencing projects become available, new approaches are needed to determine the functions of the proteins these genes encode. We show how large-scale computational analysis can help to address this challenge by linking functional information to sequence and structural similarities using protein similarity networks. Network analyses using three functionally diverse enzyme superfamilies illustrate the use of these approaches for facile updating and comparison of available structures for a large superfamily, for creation of functional hypotheses for metagenomic sequences, and to summarize the limits of our functional knowledge about even well studied superfamilies.     

临床应用重组SARS病毒双抗原夹心诊断试剂盒的检测效果评价

严重急性呼吸综合征(severe acute respiralory syndrome,SARS)的临床表现为非典型性肺炎.继加拿大首次完成SARS病毒株Tor2的全基因组测序后[1],世界卫生组织(WTO)宣布一种新型的冠状病毒(coronavirus)是引发SARS的病原体[2,3].由于SARS具有极强的传染性和较高的病死率(5%～15%),且早期疾病体征较难与某些非SARS病毒引起的非典型肺炎相区分[4],由此导致大量疑似病例无法确诊,以及因误诊引起的交叉感染给人们造成巨大的心理压力和社会恐慌.所以,建立快速、准确的早期诊断方法显得尤为重要.目前的实验室诊断方法中,主要有基于病毒抗体检测的免疫荧光法和酶联免疫吸附试验(ELISA),以及基于基因检测的多聚酶链式反应(PCR)和基因芯片法.其中ELISA主要是使用病毒裂解抗原,检测病毒IgG及IgM抗体的间接ELISA.由于病毒裂解抗原的复杂性,以及间接ELISA中二抗带来的假阳性结果,间接ELISA试剂在正常人群中有1.5%～2%的阳性结果.     

用数学模型分析非典型肺炎预防和隔离措施的有效性

利用时滞常微分方程建立数学模型,研究在无任何预防和隔离措施的假想情况下非典型肺炎传染和发展的终极状态．通过对模型的讨论发现,在无任何预防和隔离措施的情况下,当非典疫情自生自灭以后,感染非典型肺炎的总人数占总人口的比例z主要取决于基本传染数R,即每个“非典”患者在其整个病程中的平均传染人数．根据有关报道[3,4],非典型肺炎的基本传染数R在2．2至3．6之间．根据我们的模型分析,当R=2．2时,z值可达85％左右,而当R=3．6时,z值可达97％左右．而事实上由于采取了预防和隔离措施,以北京市为例,感染非典型肺炎的总人数只有几千人,不到其总人口的千分之一．这充分说明了有关非典的预防和隔离措施的有效性．     

Understanding SARS with Wolfram approach

Stepping acquired immunodeficiency syndrome (AIDS), severe acute respiratory syndrome (SARS) as another type of disease has been threatening mankind since late last year. Many scientists worldwide are making great efforts to study the etiology of this disease with different approaches. 13 species of SARS virus have been sequenced. However, most people still largely rely on the traditional methods with some disadvantages. In this work, we used Wolfram approach to study the relationship among SARS viruses and between SARS viruses and other types of viruses, the effect of variations on the whole genome and the advantages in the analysis of SARS based on this novel approach. As a result, the similarities between SARS viruses and other coronavirusxes are not really higher than those between SARS viruses and non-coronaviruses.     

抗体与SARS研究

在非典型性肺炎（SARS）的研究过程中,抗体无论在临床医学领域,还是在基础病毒学研究领域都发挥着重要的作用。利用重组蛋白或者人工合成的多肽免疫得到的针对SARS病毒特异性的单克隆、多克隆抗体可以用于SARS病人的临床血清学检测、SARS的预防治疗,还可以用于病毒蛋白的功能性研究。因此,抗体在类似SARS这样的感染性疾病研究过程中有着极大的应用价值。     

Co-evolution and co-adaptation in protein networks

Interacting or functionally related proteins have been repeatedly shown to have similar phylogenetic trees. Two main hypotheses have been proposed to explain this fact. One involves compensatory changes between the two protein families (co-adaptation). The other states that the tree similarity may be an indirect consequence of the involvement of the two proteins in similar cellular process, which in turn would be reflected by similar evolutionary pressure on the corresponding sequences. There are published data supporting both propositions, and currently the available information is compatible with both hypotheses being true, in an scenario in which both sets of forces are shaping the tree similarity at different levels.     

Evaluation of a non-prime site substituent and warheads combined with a decahydroisoquinolin scaffold as a SARS 3CL protease inhibitor

A non-prime site substituent and warheads combined with a decahydroisoquinolin scaffold was evaluated as a novel inhibitor for severe acute respiratory syndrome (SARS) chymotrypsin-like protease (3CL^pro). The decahydroisoquinolin scaffold has been demonstrated to be an effective hydrophobic center to interact with S2 site of SARS 3CL^pro, but the lack of interactions at S3 to S4 site is thought to be a major reason for the moderate inhibitory activity. In this study, the effects of an additional non-prime site substituent on the scaffold as well as effects of several warheads are evaluated. For the introduction of a desired non-prime site substituent, amino functionality was introduced on the decahydroisoquinolin scaffold, and the scaffold was constructed by Pd(II) catalyzed diastereoselective ring formation. The synthesized decahydroisoquinolin inhibitors showed about 2.4 times potent inhibitory activities for SARS 3CL^pro when combined with a non-prime site substituent. The present results indicated not only the expected additional interactions with the SARS 3CL^pro but also the possibility of new inhibitors containing a fused-ring system as a hydrophobic scaffold and a new warhead such as thioacetal.     

Maturation Mechanism of Severe Acute Respiratory Syndrome (SARS) Coronavirus 3C-like Proteinase

The 3C-like proteinase (3CL^pro) of the severe acute respiratory syndrome (SARS) coronavirus plays a vital role in virus maturation and is proposed to be a key target for drug design against SARS. Various in vitro studies revealed that only the dimer of the matured 3CL^pro is active. However, as the internally encoded 3CL^pro gets matured from the replicase polyprotein by autolytic cleavage at both the N-terminal and the C-terminal flanking sites, it is unclear whether the polyprotein also needs to dimerize first for its autocleavage reaction. We constructed a large protein containing the cyan fluorescent protein (C), the N-terminal flanking substrate peptide of SARS 3CL^pro (XX), SARS 3CL^pro (3CLP), and the yellow fluorescent protein (Y) to study the autoprocessing of 3CL^pro using fluorescence resonance energy transfer. In contrast to the matured 3CL^pro, the polyprotein, as well as the one-step digested product, 3CLP-Y-His, were shown to be monomeric in gel filtration and analytic ultracentrifuge analysis. However, dimers can still be induced and detected when incubating these large proteins with a substrate analog compound in both chemical cross-linking experiments and analytic ultracentrifuge analysis. We also measured enzyme activity under different enzyme concentrations and found a clear tendency of substrate-induced dimer formation. Based on these discoveries, we conclude that substrate-induced dimerization is essential for the activity of SARS-3CL^pro in the polyprotein, and a modified model for the 3CL^pro maturation process was proposed. As many viral proteases undergo a similar maturation process, this model might be generally applicable.     

Peptides from the SARS-associated coronavirus as tags for protein expression and purification

Protein tagging with a peptide is a commonly used technique to facilitate protein detection and to carry out protein purification. Flexibility with respect to the peptide tag is essential since no single tag suites all purposes. This report describes the usage of two short peptides from the SARS-associated coronavirus nucleocapsid (SARS-N) protein as protein tags. Plasmids for the generation of tagged proteins were generated by ligating synthetic oligonucleotides for the peptide-coding regions downstream of the protein coding sequence. The data show recognition of prokaryotically expressed HIV-1 Gag/p24 fusion protein by Western blot and efficient affinity purification using monoclonal antibodies against the tags. The SARS peptide antibody system described presents an alternative tagging opportunity in the growing field of protein science.     

Susceptibility to COVID‐19 in populations with health disparities: Posited involvement of mitochondrial disorder,socioeconomic stress,and pollutants

SARS‐CoV‐2 is a novel betacoronavirus that has caused the global health crisis known as COVID‐19. The implications of mitochondrial dysfunction with COVID‐19 are discussed as well as deregulated mitochondria and inter‐organelle functions as a posited comorbidity enhancing detrimental outcomes. Many environmental chemicals (ECs) and endocrine‐disrupting chemicals can do damage to mitochondria and cause mitochondrial dysfunction. During infection, SARS‐CoV‐2 via its binding target ACE2 and TMPRSS2 can disrupt mitochondrial function. Viral genomic RNA and structural proteins may also affect the normal function of the mitochondria‐endoplasmic reticulum‐Golgi apparatus. Drugs considered for treatment of COVID‐19 should consider effects on organelles including mitochondria functions. Mitochondrial self‐balance and clearance via mitophagy are important in SARS‐CoV‐2 infection, which indicate monitoring and protection of mitochondria against SARS‐CoV‐2 are important. Mitochondrial metabolomic analysis may provide new indicators of COVID‐19 prognosis. A better understanding of the role of mitochondria during SARS‐CoV‐2 infection may help to improve intervention therapies and better protect mitochondrial disease patients from pathogens as well as people living with poor nutrition and elevated levels of socioeconomic stress and ECs.     

Reflections on a century of protein chemistry

The development of protein structural chemistry during the twentieth century is briefly reviewed. Emphasis is placed on certain major problems that have defined the field, and how they have been resolved, often as a consequence of technological advances. The ways in which incorrect hypotheses have affected the development of the field are also discussed.     

Computational analysis of human protein interaction networks

Large amounts of human protein interaction data have been produced by experiments and prediction methods. However, the experimental coverage of the human interactome is still low in contrast to predicted data. To gain insight into the value of publicly available human protein network data, we compared predicted datasets, high-throughput results from yeast two-hybrid screens, and literature-curated protein-protein interactions. This evaluation is not only important for further methodological improvements, but also for increasing the confidence in functional hypotheses derived from predictions. Therefore, we assessed the quality and the potential bias of the different datasets using functional similarity based on the Gene Ontology, structural iPfam domain-domain interactions, likelihood ratios, and topological network parameters. This analysis revealed major differences between predicted datasets, but some of them also scored at least as high as the experimental ones regarding multiple quality measures. Therefore, since only small pair wise overlap between most datasets is observed, they may be combined to enlarge the available human interactome data. For this purpose, we additionally studied the influence of protein length on data quality and the number of disease proteins covered by each dataset. We could further demonstrate that protein interactions predicted by more than one method achieve an elevated reliability.     

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.     

Recognition and analysis of protein-coding genes in severe acute respiratory syndrome associated coronavirus

MOTIVATION: The recent outbreak of severe acute respiratory syndrome (SARS) caused by SARS coronavirus (SARS-CoV) has necessitated an in-depth molecular understanding of the virus to identify new drug targets. The availability of complete genome sequence of several strains of SARS virus provides the possibility of identification of protein-coding genes and defining their functions. Computational approach to identify protein-coding genes and their putative functions will help in designing experimental protocols. RESULTS: In this paper, a novel analysis of SARS genome using gene prediction method GeneDecipher developed in our laboratory has been presented. Each of the 18 newly sequenced SARS-CoV genomes has been analyzed using GeneDecipher. In addition to polyprotein 1ab(1), polyprotein 1a and the four genes coding for major structural proteins spike (S), small envelope (E), membrane (M) and nucleocapsid (N), six to eight additional proteins have been predicted depending upon the strain analyzed. Their lengths range between 61 and 274 amino acids. Our method also suggests that polyprotein 1ab, polyprotein 1a, S, M and N are proteins of viral origin and others are of prokaryotic. Putative functions of all predicted protein-coding genes have been suggested using conserved peptides present in their open reading frames. AVAILABILITY: Detailed results of GeneDecipher analysis of all the 18 strains of SARS-CoV genomes are available at http://www.igib.res.in/sarsanalysis.html     

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.     

SARS冠状病毒E蛋白基因的克隆与表达

E蛋白是存在于SARS病毒表面的一个小分子蛋白,在病毒的出芽过程中有重要的作用。为建立一种检测SARS病毒抗原的新方法,将E蛋白全基因序列分段合成,用连接酶连接后插入pET—GST载体,转化大肠杆菌BL21进行融合表达,结果得以成功表达GST-E融合蛋白;为SARS病毒致病机理研究和疫苗及诊断试剂的研制打下了基础。     

Altered p38 mitogen-activated protein kinase expression in different leukocytes with increment of immunosuppressive mediators in patients with severe acute respiratory syndrome

Severe acute respiratory syndrome (SARS) has spread to a global pandemic, especially in Asia. The transmission route of SARS has been clarified, but the immunopathogenesis of SARS is unclear. In an age-matched case-control design, we studied immune parameters in 15 SARS patients who were previously healthy. Plasma was harvested for detection of virus load, cytokines, and nitrite/nitrate levels, and blood leukocytes were subjected to flow cytometric analysis of intracellular mitogen-activated protein kinases (MAPKs) in different leukocytes. Patients with SARS had significantly higher IL-8 levels (p = 0.016) in early stage, and higher IL-2 levels (p = 0.039) in late stage than normal controls. Blood TNF-alpha, IL-6, and IL-10, and nitrite/nitrate levels were not significantly elevated. In contrast, TGF-beta and PGE(2) levels were significantly elevated in SARS patients. Five of the 15 SARS patients had detectable coronaviruses in blood, but patients with detectable and undetectable viremia had no different profiles of immune mediators. Flow cytometric analysis of MAPKs activation by phospho-p38 and phospho-p44/42 (extracellular signal-regulated kinase) expression showed that augmented p38 activation (p = 0.044) of CD14 monocytes associated with suppressed p38 activation (p = 0.033) of CD8 lymphocytes was found in SARS patients. These results suggest that regulation of TGF-beta and PGE(2) production and MAPKs activation in different leukocytes may be considered while developing therapeutics for the SARS treatment.