Chi Fon Chang scite author profile

The nucleocapsid phosphoprotein of the severe acute respiratory syndrome coronavirus (SARS-CoV N protein) packages the viral genome into a helical ribonucleocapsid (RNP) and plays a fundamental role during viral self-assembly. It is a protein with multifarious activities. In this article we will review our current understanding of the N protein structure and its interaction with nucleic acid. Highlights of the progresses include uncovering the modular organization, determining the structures of the structural domains, realizing the roles of protein disorder in protein-protein and protein-nucleic acid interactions, and visualizing the ribonucleoprotein (RNP) structure inside the virions. It was also demonstrated that N-protein binds to nucleic acid at multiple sites with a coupled-allostery manner. We propose a SARS-CoV RNP model that conforms to existing data and bears resemblance to the existing RNP structures of RNA viruses. The model highlights the critical role of modular organization and intrinsic disorder of the N protein in the formation and functions of the dynamic RNP capsid in RNA viruses. This paper forms part of a symposium in Antiviral Research on "From SARS to MERS: 10 years of research on highly pathogenic human coronaviruses."

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The dimer interface of the SARS coronavirus nucleocapsid protein adapts a porcine respiratory and reproductive syndrome virus‐like structure

Chang

Sue

et al. 2005

FEBS Letters

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We have employed NMR to investigate the structure of SARS coronavirus nucleocapsid protein dimer. We found that the secondary structure of the dimerization domain consists of five a helices and a b-hairpin. The dimer interface consists of a continuous four-stranded b-sheet superposed by two long a helices, reminiscent of that found in the nucleocapsid protein of porcine respiratory and reproductive syndrome virus. Extensive hydrogen bond formation between the two hairpins and hydrophobic interactions between the b-sheet and the a helices render the interface highly stable. Sequence alignment suggests that other coronavirus may share the same structural topology.

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Molecular mechanism of oxidation‐induced TDP‐43 RRM1 aggregation and loss of function

et al. 2013

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Cysteine oxidation of the two RNA recognition motifs (RRM1 and RRM2) of TDP-43, a multi-domain protein involved in neurodegenerative diseases, results in loss of function and accumulation of insoluble aggregates under both in vitro and in vivo conditions. However, the molecular mechanisms linking cysteine oxidation to protein aggregation and functional aberration remain unknown. We report that oxidation of cysteines in RRM1, but not in other domains, induced conformational changes which subsequently resulted in protein aggregation and loss of nucleic acid-binding activity. Thus, oxidation-induced conformational change of RRM1 plays a key role in TDP-43 aggregation and disease progression.

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Structural analysis of poly-SUMO chain recognition by the RNF4-SIMs domain

Kung

Naik

Wang

et al. 2014

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The E3 ubiquitin ligase RNF4 (RING finger protein 4) contains four tandem SIM [SUMO (small ubiquitin-like modifier)-interaction motif] repeats for selective interaction with poly-SUMO-modified proteins, which it targets for degradation. We employed a multi-faceted approach to characterize the structure of the RNF4-SIMs domain and the tetra-SUMO2 chain to elucidate the interaction between them. In solution, the SIM domain was intrinsically disordered and the linkers of the tetra-SUMO2 were highly flexible. Individual SIMs of the RNF4-SIMs domains bind to SUMO2 in the groove between the β2-strand and the α1-helix parallel to the β2-strand. SIM2 and SIM3 bound to SUMO with a high affinity and together constituted the recognition module necessary for SUMO binding. SIM4 alone bound to SUMO with low affinity; however, its contribution to tetra-SUMO2 binding avidity is comparable with that of SIM3 when in the RNF4-SIMs domain. The SAXS data of the tetra-SUMO2-RNF4-SIMs domain complex indicate that it exists as an ordered structure. The HADDOCK model showed that the tandem RNF4-SIMs domain bound antiparallel to the tetra-SUMO2 chain orientation and wrapped around the SUMO protamers in a superhelical turn without imposing steric hindrance on either molecule.

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Structural dynamics of the two-component response regulator RstA in recognition of promoter DNA element

Li¹,

Chang²,

Chang³

et al. 2014

Nucleic Acids Res

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The RstA/RstB system is a bacterial two-component regulatory system consisting of the membrane sensor, RstB and its cognate response regulator (RR) RstA. The RstA of Klebsiella pneumoniae (kpRstA) consists of an N-terminal receiver domain (RD, residues 1–119) and a C-terminal DNA-binding domain (DBD, residues 130–236). Phosphorylation of kpRstA induces dimerization, which allows two kpRstA DBDs to bind to a tandem repeat, called the RstA box, and regulate the expression of downstream genes. Here we report the solution and crystal structures of the free kpRstA RD, DBD and DBD/RstA box DNA complex. The structure of the kpRstA DBD/RstA box complex suggests that the two protomers interact with the RstA box in an asymmetric fashion. Equilibrium binding studies further reveal that the two protomers within the kpRstA dimer bind to the RstA box in a sequential manner. Taken together, our results suggest a binding model where dimerization of the kpRstA RDs provides the platform to allow the first kpRstA DBD protomer to anchor protein–DNA interaction, whereas the second protomer plays a key role in ensuring correct recognition of the RstA box.

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Chi Fon Chang

The SARS coronavirus nucleocapsid protein – Forms and functions

The dimer interface of the SARS coronavirus nucleocapsid protein adapts a porcine respiratory and reproductive syndrome virus‐like structure

Molecular mechanism of oxidation‐induced TDP‐43 RRM1 aggregation and loss of function

Structural analysis of poly-SUMO chain recognition by the RNF4-SIMs domain

Structural dynamics of the two-component response regulator RstA in recognition of promoter DNA element

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