Hui-Chuan Chang scite author profile

Severe acute respiratory syndrome (SARS) is an emerging infectious disease caused by a novel human coronavirus. Viral maturation requires a main protease (3CL pro ) to cleave the virus-encoded polyproteins. We report here that the 3CL pro containing additional N-and/or C-terminal segments of the polyprotein sequences undergoes autoprocessing and yields the mature protease in vitro. The dimeric three-dimensional structure of the C145A mutant protease shows that the active site of one protomer binds with the C-terminal six amino acids of the protomer from another asymmetric unit, mimicking the product-bound form and suggesting a possible mechanism for maturation. The P1 pocket of the active site binds the Gln side chain specifically, and the P2 and P4 sites are clustered together to accommodate large hydrophobic side chains. The tagged C145A mutant protein served as a substrate for the wild-type protease, and the N terminus was first digested (55-fold faster) at the Gln The data indicate that immature 3CL pro can form dimer enabling it to undergo autoprocessing to yield the mature enzyme, which further serves as a seed for facilitated maturation. Taken together, this study provides insights into the maturation process of the SARS 3CL pro from the polyprotein and design of new structure-based inhibitors.

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Critical Assessment of Important Regions in the Subunit Association and Catalytic Action of the Severe Acute Respiratory Syndrome Coronavirus Main Protease

Hsu¹,

Chang²,

Chou³

et al. 2005

Journal of Biological Chemistry

123

169

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The severe acute respiratory syndrome (SARS) coronavirus (CoV) main protease represents an attractive target for the development of novel anti-SARS agents. The tertiary structure of the protease consists of two distinct folds. One is the N-terminal chymotrypsin-like fold that consists of two structural domains and constitutes the catalytic machinery; the other is the C-terminal helical domain, which has an unclear function and is not found in other RNA virus main proteases. To understand the functional roles of the two structural parts of the SARS-CoV main protease, we generated the fulllength of this enzyme as well as several terminally truncated forms, different from each other only by the number of amino acid residues at the C-or N-terminal regions. The quaternary structure and K d value of the protease were analyzed by analytical ultracentrifugation. The results showed that the N-terminal 1-3 amino acid-truncated protease maintains 76% of enzyme activity and that the major form is a dimer, as in the wild type. However, the amino acids 1-4-truncated protease showed the major form to be a monomer and had little enzyme activity. As a result, the fourth amino acid seemed to have a powerful effect on the quaternary structure and activity of this protease. The last C-terminal helically truncated protease also exhibited a greater tendency to form monomer and showed little activity. We concluded that both the C-and the N-terminal regions influence the dimerization and enzyme activity of the SARS-CoV main protease.

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Correlation between dissociation and catalysis of SARS-CoV main protease

Lin¹,

Chou²,

Chang³

et al. 2008

Archives of Biochemistry and Biophysics

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The dimeric interface of severe acute respiratory syndrome coronavirus main protease is a potential target for the anti-SARS drug development. We have generated C-terminal truncated mutants by serial truncations. The quaternary structure of the enzyme was analyzed using both sedimentation velocity and sedimentation equilibrium analytical ultracentrifugation. Global analysis of the combined results showed that truncation of C-terminus from 306 to 300 had no appreciable effect on the quaternary structure, and the enzyme remained catalytically active. However, further deletion of Gln-299 or Arg-298 drastically decreased the enzyme activity to 1-2% of wild type (WT), and the major form was a monomeric one. Detailed analysis of the point mutants of these two amino acid residues and their nearby hydrogen bond partner Ser-123 and Ser-139 revealed a strong correlation between the enzyme activity loss and dimer dissociation.

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Crystal Structure of Bacillus subtilis Guanine Deaminase

Liaw

Chang

Lai³

et al. 2004

Journal of Biological Chemistry

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Guanine deaminase, a key enzyme in the nucleotide metabolism, catalyzes the hydrolytic deamination of guanine into xanthine. The crystal structure of the 156-residue guanine deaminase from Bacillus subtilis has been solved at 1.17-Å resolution. Unexpectedly, the Cterminal segment is swapped to form an intersubunit active site and an intertwined dimer with an extensive interface of 3900 Å 2 per monomer. . The closed conformation also reveals that substrate binding seals the active site entrance, which is controlled by the C-terminal tail. Therefore, the domain swapping has not only facilitated the dimerization but has also ensured specific substrate recognition. Finally, a detailed structural comparison of the cytidine deaminase superfamily illustrates the functional versatility of the divergent active sites found in the guanine, cytosine, and cytidine deaminases and suggests putative specific substrate-interacting residues for other members such as dCMP deaminases.

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Involvement of Single Residue Tryptophan 548 in the Quaternary Structural Stability of Pigeon Cytosolic Malic Enzyme

Chang¹,

Chang²

2003

Journal of Biological Chemistry

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Hui-Chuan Chang

Mechanism of the Maturation Process of SARS-CoV 3CL Protease

Critical Assessment of Important Regions in the Subunit Association and Catalytic Action of the Severe Acute Respiratory Syndrome Coronavirus Main Protease

Correlation between dissociation and catalysis of SARS-CoV main protease

Crystal Structure of Bacillus subtilis Guanine Deaminase

Involvement of Single Residue Tryptophan 548 in the Quaternary Structural Stability of Pigeon Cytosolic Malic Enzyme

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